Codeofchina.com is in charge of this English translation. In case of any doubt about the English translation, the Chinese original shall be considered authoritative.
This standard is identical to the standard ISO 11042-1:1996 of International Organization for Standardization (ISO).
The following editorial changes have been made with respect to the original ISO 11042-1:1996:
——the contents of the amendment or technical corrigendum of the international standard are incorporated;
——the standard name is changed;
——the informative annexes are added;
——the content on unit conversion is added.
This standard was proposed by National Technical Committee on Combine-cycle Power Generation Unit in Power Industry of Standardization Administration of China.
This standard is under the jurisdiction of and explained by National Technical Committee on Combine-cycle Power Generation Unit in Power Industry of Standardization Administration of China.
During the process of implementing this standard, the relevant comments and recommendations, whenever necessary, can be fed back to the Standardization Center of the China Electricity Council (No.1, 2nd lane, Baiguang Road, Beijing, 100761, China).
Gas turbine-exhaust gas emission: measurement and evaluation
1 Scope
This standard establishes the methods used for the measurement and evaluation of the emission of the exhaust gases from gas turbines and defines appropriate emission terms. It presents requirements for the test environment and instrumentation as well as the quality of measurement and correction of data. This allows uniform judgment of the exhaust emissions. The relationship between the various forms of expressing the exhaust emissions is also given.
The constituents to be measured in accordance with this standard shall be determined by mutual agreement between the parties involved.
This standard is applicable for all gas turbines producing mechanical shaft power and/or which are used as drivers for electrical generation excluding application in aircraft. For installations which include an exhaust gas heat recuperation system, the definitions of this standard can be used as a basis.
This standard is applicable for gas turbines which utilize the open cycle process. It is also applicable as a basis for gas turbines which utilize the semi-closed cycle and gas turbines equipped with free piston compressors or with special heat sources.
This standard can be used as an acceptance test for gas turbine exhaust gas emissions.
2 Normative references
The following documents for the application of this document are essential. Any dated reference, just dated edition applies to this document. For undated references, the latest edition of the normative document (including any amendments) applies.
GB/T 14100-1993 Gas turbines - Acceptance tests (ISO 2314:1989, IDT)
ISO 2533:1975 Standard atmosphere
ISO 5063:1978 Atomizing oil burners of the monobloc type - Testing
ISO 6141:1984 Gas analysis - Calibration gas mixtures - Certificate of mixture preparation
3 Terms and definitions
For the purpose of this standard, the following terms and definitions apply.
3.1
emissions
constituents which enter the environment with the exhaust gas
In this standard, emissions comprise the following:
nitrogen oxides NOx: sum of NO and NO2, expressed as NO2
nitrogen dioxide NO2
carbon monoxide CO
carbon dioxide CO2
sulfur oxides SOx: sum of SO2 and SO3, expressed as SO2
unburned or partially burned hydrocarbon products UHCs: sum of all individual products, expressed as CH4
volatile organic compounds VOCs: UHCs excluding CH4 and C2H6 but expressed as CH4
ammonia NH3
smoke as measured by the Bacharach method according to ISO 5063:1978
solid particles all solid particles produced by the combustion process
3.2
accuracy
the closeness with which a measurement approaches the true value established independently
3.3
calibration gas
high-accuracy reference gas mixture to be used for setting, adjustment and periodic checks of instruments
3.4
concentration
volume fraction φi of the component of interest in the gas mixture, expressed as volume percentage [(% (V/V)] or as parts per million (ppm )
3.5
interference
instrument response due to the presence of a gas or vapour other than the gas or vapour that is to be measured
3.6
linearity
ability of an instrument to respond proportionally to an input signal
3.7
noise
random variation in instrument output not associated with those characteristics of the sample to which the instrument is responding; distinguishable from its drift characteristics
3.8
parts per million; ppm
volumetric concentration of the component i in 106 volume parts of gas mixture
3.9
parts per million carbon; ppmC1
the mole fraction of hydrocarbon multiplied by 106 measured on a “CH4” equivalence basis
1ppm of methane is indicated as 1ppmC1.
Note: to convert ppm concentration of any hydrocarbon to an equivalent ppmC1 value, multiply ppm concentration by the number of carbon atoms per molecule of the gas; e.g. 1ppm propane translates as 3ppmC1 hydrocarbon; 1ppm hexane as 6ppmC1 hydrocarbon.
3.10
repeatability
the closeness with which a measurement upon a given invariant sample can be produced on a short-term basis with no adjustment of the instruments
3.11
resolution
smallest detectable change in a measurement
3.12
response
change in instrument output signal that occurs with change in sample concentration; output signal corresponding to a given sample concentration
3.13
stability/calibration drift
time-related deviations of the output signal of the instrument measuring a calibration gas for a given set point
3.14
relative hydrocarbon response
the different response of the test equipment to the sample hydrocarbon concentrations expressed as equivalent ppmC1, dependent on the class or admixture of classes of hydrocarbon components
3.15
zero air
mixture of oxygen and nitrogen having the same proportion of oxygen as atmospheric air, free from other components
3.16
zero drift
time-related deviation of instrument output from zero set point when it is operating on a gas free of the component to be measured
3.17
zero gas
has to be used in establishing the zero, or no-response, adjustment of an instrument
4 Symbols
See Tables 1 and 2.
Table 1 General symbols
Symbol Term Unit
en Net specific energy, lower calorific value kJ/kg
E Exhaust gas emission value —
EMi Exhaust gas emission value as constituent concentration of component i at 0℃ and 101.3kPa mg/m3
EMi,15,dry Same as EMi, related to an oxygen volumetric concentration of 15% in dry exhaust gas mg/m3
EMi,f Same as EMi, related to consumed fuel energy g/GJ
EMi,p Same as EMi, related to power supplied g/kWh
EP Exhaust gas emission value for solid particles mg/m3
ES Exhaust gas emission value for smoke —
EV Exhaust gas emission value as a volumetric concentration cm3/m3
EVi Exhaust gas emission value as a volumetric concentration of component i cm3/m3
EVi,15,dry Same as EVi, related to an oxygen volumetric concentration of 15% in dry exhaust gas cm3/m3
m Mass kg
M Molar mass kg/kmol
Mtot Total molar mass kg/kmol
n Quantity of component kmol
ni Quantity of component i kmol
ntot Total quantity of components kmol
P Shaft power output of gas turbine kW
qm Mass flow kg/s
qV Volume flow m3/s
Vi Volume of component i m3
Vmn Molar specific volume m3/kmol
Vn,dry Volume of dry exhaust gas at normal conditions a m3
Vn,15,dry Volume of dry exhaust gas at normal conditions related to an oxygen content of 15% m3
Vn,wet Volume of wet exhaust gas at normal conditions a m3
Vtot Total volume of components i m3
xi Partial quantity, equal to ni/ntot 1
z Limiting number 1
Z Real gas factor (compressibility) 1
ρ Density kg/m3
ρpa Density of particle material kg/m3
Volumetric concentration as percentage of CO2 in dry exhaust gas %
Volumetric concentration as percentage of CO2 in dry exhaust gas with stoichiometric combustion of the fuel used %
Volumetric concentration as percentage of water vapour in exhaust gas %
φi,dry Volumetric concentration in dry exhaust gas cm3/m3
φi,wet Volumetric concentration in wet exhaust gas, equal to Vi/Vtot cm3/m3
Volumetric concentration as percentage of O2 in dry exhaust gas %
Note 1: to identify a particular station along the gas path the subscript g is used, e.g. g7. Subscript 7 identifies the turbine outlet (see ISO 2314:1989).
Note 2: in this standard, 15% O2 is used as a typical value; alternative oxygen contents may be used by agreement.
Note 3: the reference temperature of 0℃ is chosen because of available chemical data and evaluation methods.
a Normal pressure: pn=101.3kPa
Normal temperature: tn=0℃
Table 2 Chemical symbols and abbreviations
Symbol Compound
CO Carbon monoxide
CO2 Carbon dioxide
H2O Water
N2 Nitrogen
NH3 Ammonia
NO Nitrogen monoxide
NO2 Nitrogen dioxide
NOx Sum of nitrogen oxides
O2 Oxygen
SO2 Sulfur dioxide
SO3 Sulfur trioxide
SOx Sum of sulfur oxides
UHC Unburned or partially burned hydrocarbon products
VOC Volatile organic compounds
5 Conditions
5.1 Gas turbine and fuel
In connection with gas turbine emissions, the following shall be indicated for the respective measurement conditions:
a) Manufacturer of the gas turbine.
b) Type of gas turbine.
c) Power output and exhaust gas mass flow and/or fuel flow at the conditions at which the emission measurements are taken.
d) Ambient conditions, i.e. pressure, temperature and humidity of the surrounding air.
e) Fuel details.
f) Equipment in operation which affects the emissions and which is part of the complete system, e.g. catalytic converters, water or steam injection, evaporative coolers, condensers, etc. Relevant details of all flow rates shall be noted.
Note 1: the definition of the power output, the exhaust gas mass flow rate and/or the fuel flow rate, the measurements and calculations shall be defined by agreement between the parties involved (see ISO 2314:1989).
Note 2: Exhaust gas emissions are affected by the fuel characteristics (e.g. fuel-bound nitrogen). Therefore, relevant details of the fuel shall be noted, including appropriate chemical analysis, temperature, physical properties and flow rates
5.2 Measured values
The following values shall be measured:
a) Volumetric concentration of gaseous constituents related to wet exhaust gas (φi,wet) or to dry exhaust gas (φi,dry).
b) Exhaust gas emission value for smoke - Bacharach number (ES) (smoke number according to ISO 2314:1989).
c) Gravimetric concentration of solid particles within the wet exhaust gas (EP), if specifically agreed upon.
Foreword II
1 Scope
2 Normative references
3 Terms and definitions
4 Symbols
5 Conditions
5.1 Gas turbine and fuel
5.2 Measured values
5.3 Standard conditions
6 Measurements
6.1 Determination of constituents in exhaust gas
6.2 Guidelines for the arrangement of the measurement system
6.3 Performing the test, test report, evaluation
7 Instrumentation
7.1 Types of measuring device
7.2 Specification for NOx analysers
7.3 Specification for NO2 analysers
7.4 Specification for SO2 analysers
7.5 Specification for UHC analysers
7.6 Specification for ammonia analysers
7.7 Specification for oxygen analysers
7.8 Specification for smoke analysers
7.9 Specification for solid particle analysers
8 Quality of measurement
8.1 General
8.2 Methods for calibration
9 Conversion of data
9.1 General
9.2 Conversion between wet and dry exhaust gas
9.3 Conversion to the particular exhaust gas oxygen level
9.4 Conversion to the constituent mass flow related to the dry exhaust gas volume flow at normal conditions and to a specific oxygen content
9.5 Conversion to power output related values
9.6 Conversion to consumed fuel energy related values
Annex A (informative) Typical example of test results and their evaluation
Annex B (informative) Information regarding the major constituents of the exhaust gas
Annex C (Informative) Physical properties of gaseous constituents
Bibliography
Codeofchina.com is in charge of this English translation. In case of any doubt about the English translation, the Chinese original shall be considered authoritative.
This standard is identical to the standard ISO 11042-1:1996 of International Organization for Standardization (ISO).
The following editorial changes have been made with respect to the original ISO 11042-1:1996:
——the contents of the amendment or technical corrigendum of the international standard are incorporated;
——the standard name is changed;
——the informative annexes are added;
——the content on unit conversion is added.
This standard was proposed by National Technical Committee on Combine-cycle Power Generation Unit in Power Industry of Standardization Administration of China.
This standard is under the jurisdiction of and explained by National Technical Committee on Combine-cycle Power Generation Unit in Power Industry of Standardization Administration of China.
During the process of implementing this standard, the relevant comments and recommendations, whenever necessary, can be fed back to the Standardization Center of the China Electricity Council (No.1, 2nd lane, Baiguang Road, Beijing, 100761, China).
Gas turbine-exhaust gas emission: measurement and evaluation
1 Scope
This standard establishes the methods used for the measurement and evaluation of the emission of the exhaust gases from gas turbines and defines appropriate emission terms. It presents requirements for the test environment and instrumentation as well as the quality of measurement and correction of data. This allows uniform judgment of the exhaust emissions. The relationship between the various forms of expressing the exhaust emissions is also given.
The constituents to be measured in accordance with this standard shall be determined by mutual agreement between the parties involved.
This standard is applicable for all gas turbines producing mechanical shaft power and/or which are used as drivers for electrical generation excluding application in aircraft. For installations which include an exhaust gas heat recuperation system, the definitions of this standard can be used as a basis.
This standard is applicable for gas turbines which utilize the open cycle process. It is also applicable as a basis for gas turbines which utilize the semi-closed cycle and gas turbines equipped with free piston compressors or with special heat sources.
This standard can be used as an acceptance test for gas turbine exhaust gas emissions.
2 Normative references
The following documents for the application of this document are essential. Any dated reference, just dated edition applies to this document. For undated references, the latest edition of the normative document (including any amendments) applies.
GB/T 14100-1993 Gas turbines - Acceptance tests (ISO 2314:1989, IDT)
ISO 2533:1975 Standard atmosphere
ISO 5063:1978 Atomizing oil burners of the monobloc type - Testing
ISO 6141:1984 Gas analysis - Calibration gas mixtures - Certificate of mixture preparation
3 Terms and definitions
For the purpose of this standard, the following terms and definitions apply.
3.1
emissions
constituents which enter the environment with the exhaust gas
In this standard, emissions comprise the following:
nitrogen oxides NOx: sum of NO and NO2, expressed as NO2
nitrogen dioxide NO2
carbon monoxide CO
carbon dioxide CO2
sulfur oxides SOx: sum of SO2 and SO3, expressed as SO2
unburned or partially burned hydrocarbon products UHCs: sum of all individual products, expressed as CH4
volatile organic compounds VOCs: UHCs excluding CH4 and C2H6 but expressed as CH4
ammonia NH3
smoke as measured by the Bacharach method according to ISO 5063:1978
solid particles all solid particles produced by the combustion process
3.2
accuracy
the closeness with which a measurement approaches the true value established independently
3.3
calibration gas
high-accuracy reference gas mixture to be used for setting, adjustment and periodic checks of instruments
3.4
concentration
volume fraction φi of the component of interest in the gas mixture, expressed as volume percentage [(% (V/V)] or as parts per million (ppm )
3.5
interference
instrument response due to the presence of a gas or vapour other than the gas or vapour that is to be measured
3.6
linearity
ability of an instrument to respond proportionally to an input signal
3.7
noise
random variation in instrument output not associated with those characteristics of the sample to which the instrument is responding; distinguishable from its drift characteristics
3.8
parts per million; ppm
volumetric concentration of the component i in 106 volume parts of gas mixture
3.9
parts per million carbon; ppmC1
the mole fraction of hydrocarbon multiplied by 106 measured on a “CH4” equivalence basis
1ppm of methane is indicated as 1ppmC1.
Note: to convert ppm concentration of any hydrocarbon to an equivalent ppmC1 value, multiply ppm concentration by the number of carbon atoms per molecule of the gas; e.g. 1ppm propane translates as 3ppmC1 hydrocarbon; 1ppm hexane as 6ppmC1 hydrocarbon.
3.10
repeatability
the closeness with which a measurement upon a given invariant sample can be produced on a short-term basis with no adjustment of the instruments
3.11
resolution
smallest detectable change in a measurement
3.12
response
change in instrument output signal that occurs with change in sample concentration; output signal corresponding to a given sample concentration
3.13
stability/calibration drift
time-related deviations of the output signal of the instrument measuring a calibration gas for a given set point
3.14
relative hydrocarbon response
the different response of the test equipment to the sample hydrocarbon concentrations expressed as equivalent ppmC1, dependent on the class or admixture of classes of hydrocarbon components
3.15
zero air
mixture of oxygen and nitrogen having the same proportion of oxygen as atmospheric air, free from other components
3.16
zero drift
time-related deviation of instrument output from zero set point when it is operating on a gas free of the component to be measured
3.17
zero gas
has to be used in establishing the zero, or no-response, adjustment of an instrument
4 Symbols
See Tables 1 and 2.
Table 1 General symbols
Symbol Term Unit
en Net specific energy, lower calorific value kJ/kg
E Exhaust gas emission value —
EMi Exhaust gas emission value as constituent concentration of component i at 0℃ and 101.3kPa mg/m3
EMi,15,dry Same as EMi, related to an oxygen volumetric concentration of 15% in dry exhaust gas mg/m3
EMi,f Same as EMi, related to consumed fuel energy g/GJ
EMi,p Same as EMi, related to power supplied g/kWh
EP Exhaust gas emission value for solid particles mg/m3
ES Exhaust gas emission value for smoke —
EV Exhaust gas emission value as a volumetric concentration cm3/m3
EVi Exhaust gas emission value as a volumetric concentration of component i cm3/m3
EVi,15,dry Same as EVi, related to an oxygen volumetric concentration of 15% in dry exhaust gas cm3/m3
m Mass kg
M Molar mass kg/kmol
Mtot Total molar mass kg/kmol
n Quantity of component kmol
ni Quantity of component i kmol
ntot Total quantity of components kmol
P Shaft power output of gas turbine kW
qm Mass flow kg/s
qV Volume flow m3/s
Vi Volume of component i m3
Vmn Molar specific volume m3/kmol
Vn,dry Volume of dry exhaust gas at normal conditions a m3
Vn,15,dry Volume of dry exhaust gas at normal conditions related to an oxygen content of 15% m3
Vn,wet Volume of wet exhaust gas at normal conditions a m3
Vtot Total volume of components i m3
xi Partial quantity, equal to ni/ntot 1
z Limiting number 1
Z Real gas factor (compressibility) 1
ρ Density kg/m3
ρpa Density of particle material kg/m3
Volumetric concentration as percentage of CO2 in dry exhaust gas %
Volumetric concentration as percentage of CO2 in dry exhaust gas with stoichiometric combustion of the fuel used %
Volumetric concentration as percentage of water vapour in exhaust gas %
φi,dry Volumetric concentration in dry exhaust gas cm3/m3
φi,wet Volumetric concentration in wet exhaust gas, equal to Vi/Vtot cm3/m3
Volumetric concentration as percentage of O2 in dry exhaust gas %
Note 1: to identify a particular station along the gas path the subscript g is used, e.g. g7. Subscript 7 identifies the turbine outlet (see ISO 2314:1989).
Note 2: in this standard, 15% O2 is used as a typical value; alternative oxygen contents may be used by agreement.
Note 3: the reference temperature of 0℃ is chosen because of available chemical data and evaluation methods.
a Normal pressure: pn=101.3kPa
Normal temperature: tn=0℃
Table 2 Chemical symbols and abbreviations
Symbol Compound
CO Carbon monoxide
CO2 Carbon dioxide
H2O Water
N2 Nitrogen
NH3 Ammonia
NO Nitrogen monoxide
NO2 Nitrogen dioxide
NOx Sum of nitrogen oxides
O2 Oxygen
SO2 Sulfur dioxide
SO3 Sulfur trioxide
SOx Sum of sulfur oxides
UHC Unburned or partially burned hydrocarbon products
VOC Volatile organic compounds
5 Conditions
5.1 Gas turbine and fuel
In connection with gas turbine emissions, the following shall be indicated for the respective measurement conditions:
a) Manufacturer of the gas turbine.
b) Type of gas turbine.
c) Power output and exhaust gas mass flow and/or fuel flow at the conditions at which the emission measurements are taken.
d) Ambient conditions, i.e. pressure, temperature and humidity of the surrounding air.
e) Fuel details.
f) Equipment in operation which affects the emissions and which is part of the complete system, e.g. catalytic converters, water or steam injection, evaporative coolers, condensers, etc. Relevant details of all flow rates shall be noted.
Note 1: the definition of the power output, the exhaust gas mass flow rate and/or the fuel flow rate, the measurements and calculations shall be defined by agreement between the parties involved (see ISO 2314:1989).
Note 2: Exhaust gas emissions are affected by the fuel characteristics (e.g. fuel-bound nitrogen). Therefore, relevant details of the fuel shall be noted, including appropriate chemical analysis, temperature, physical properties and flow rates
5.2 Measured values
The following values shall be measured:
a) Volumetric concentration of gaseous constituents related to wet exhaust gas (φi,wet) or to dry exhaust gas (φi,dry).
b) Exhaust gas emission value for smoke - Bacharach number (ES) (smoke number according to ISO 2314:1989).
c) Gravimetric concentration of solid particles within the wet exhaust gas (EP), if specifically agreed upon.
Contents of DL/T 1606-2016
Foreword II
1 Scope
2 Normative references
3 Terms and definitions
4 Symbols
5 Conditions
5.1 Gas turbine and fuel
5.2 Measured values
5.3 Standard conditions
6 Measurements
6.1 Determination of constituents in exhaust gas
6.2 Guidelines for the arrangement of the measurement system
6.3 Performing the test, test report, evaluation
7 Instrumentation
7.1 Types of measuring device
7.2 Specification for NOx analysers
7.3 Specification for NO2 analysers
7.4 Specification for SO2 analysers
7.5 Specification for UHC analysers
7.6 Specification for ammonia analysers
7.7 Specification for oxygen analysers
7.8 Specification for smoke analysers
7.9 Specification for solid particle analysers
8 Quality of measurement
8.1 General
8.2 Methods for calibration
9 Conversion of data
9.1 General
9.2 Conversion between wet and dry exhaust gas
9.3 Conversion to the particular exhaust gas oxygen level
9.4 Conversion to the constituent mass flow related to the dry exhaust gas volume flow at normal conditions and to a specific oxygen content
9.5 Conversion to power output related values
9.6 Conversion to consumed fuel energy related values
Annex A (informative) Typical example of test results and their evaluation
Annex B (informative) Information regarding the major constituents of the exhaust gas
Annex C (Informative) Physical properties of gaseous constituents
Bibliography
