AGA REPORT 5-2009 Natural Gas Energy Measurement (XQ0901 Includes Access to Additional Content)《天然气能量测量.XQ0901 含补充信息访问权》.pdf

1、 Access to Additional Content for AGA Report 5: 3/2009 (Click here to view the publication) This Page is not part of the original publication This page has been added by IHS as a convenience to the user in order to provide access to additional content as authorized by the Copyright holder of this do

2、cument Click the link(s) below to access the content and use normal procedures for downloading or opening the files. AGA5_Calculation-Imperial_Unit.xls AGA5_Calculation-SI_Units.xls AGA5_Dry_Air_Mass.xls AGA5_Gross_Ideal_Heating_Value.xls AGA5_Molar_Heating_Value.xls AGA5_Summation_Factors.xls Infor

3、mation contained in the above is the property of the Copyright holder and all Notice of Disclaimer & Limitation of Liability of the Copyright holder apply. If you have any questions, or need technical assistance please contact IHS Support. IHS Additional Content Page AGA Report No. 5 Natural Gas Ene

4、rgy Measurement Prepared by Transmission Measurement Committee March 2009 AGA Report No. 5 Natural Gas Energy Measurement Prepared by Transmission Measurement Committee Copyright 2009 American Gas Association All Rights Reserved Catalog # XQ0901 ii iii DISCLAIMER AND COPYRIGHT The American Gas Assoc

5、iations (AGA) Operations and Engineering Section provides a forum for industry experts to bring collective knowledge together to improve the state of the art in the areas of operating, engineering and technological aspects of producing, gathering, transporting, storing, distributing, measuring and u

6、tilizing natural gas. Through its publications, of which this is one, AGA provides for the exchange of information within the gas industry and scientific, trade and governmental organizations. Each publication is prepared or sponsored by an AGA Operations and Engineering Section technical committee.

7、 While AGA may administer the process, neither AGA nor the technical committee independently tests, evaluates or verifies the accuracy of any information or the soundness of any judgments contained therein. AGA disclaims liability for any personal injury, property or other damages of any nature what

8、soever, whether special, indirect, consequential or compensatory, directly or indirectly resulting from the publication, use of or reliance on AGA publications. AGA makes no guaranty or warranty as to the accuracy and completeness of any information published therein. The information contained there

9、in is provided on an “as is” basis and AGA makes no representations or warranties including any expressed or implied warranty of merchantability or fitness for a particular purpose. In issuing and making this document available, AGA is not undertaking to render professional or other services for or

10、on behalf of any person or entity. Nor is AGA undertaking to perform any duty owed by any person or entity to someone else. Anyone using this document should rely on his or her own independent judgment or, as appropriate, seek the advice of a competent professional in determining the exercise of rea

11、sonable care in any given circumstances. AGA has no power, nor does it undertake, to police or enforce compliance with the contents of this document. Nor does AGA list, certify, test or inspect products, designs or installations for compliance with this document. Any certification or other statement

12、 of compliance is solely the responsibility of the certifier or maker of the statement. AGA does not take any position with respect to the validity of any patent rights asserted in connection with any items that are mentioned in or are the subject of AGA publications, and AGA disclaims liability for

13、 the infringement of any patent resulting from the use of or reliance on its publications. Users of these publications are expressly advised that determination of the validity of any such patent rights, and the risk of infringement of such rights, is entirely their own responsibility. Users of this

14、publication should consult applicable federal, state and local laws and regulations. AGA does not, through its publications intend to urge action that is not in compliance with applicable laws, and its publications may not be construed as doing so. This report is the cumulative result of years of ex

15、perience of many individuals and organizations acquainted with the measurement of natural gas. However, changes to this report may become necessary from time to time. If changes to this report are believed appropriate by any manufacturer, individual or organization, such suggested changes should be

16、communicated to AGA by completing the last page of this report titled, “Form for Proposal on AGA Report No. 5” and sending it to: Operations & Engineering Section, American Gas Association, 400 North Capitol Street, NW, 4thFloor, Washington, DC 20001, U.S.A. Copyright 2009, American Gas Association,

17、 All Rights Reserved. iv ACKNOWLEDGEMENTS AGA Report No. 5, Natural Gas Energy Measurement, was revised by a Task Group of the American Gas Associations Transmission Measurement Committee under the joint chairmanship of Warren Peterson with TransCanada Pipelines Limited and James Witte with El Paso

18、Corporation with substantial contributions from Eric Lemmon with the National Institute of Standards and Technology. Individuals who made considerable contributions to the revision of this document are: Kenneth Starling, Starling Associates, Inc. Paul LaNasa, CPL & Associates Paul Kizer, Formerly wi

19、th ABB, Inc. Other individuals who also contributed to the revision of the document are: Stephen Hall, TransCanada Pipelines Limited Thanh Phan, Spectra Energy Corp. Joe Bronner, Pacific Gas and Electric Company Hank Poellnitz, Southern Natural Gas Company Eric Kelner, Formerly with Southwest Resear

20、ch Institute Ed Bowles, Southwest Research Institute Mark Maxwell, Instromet, Inc. Frank Brown, Consultant AGA acknowledges the contributions of the above individuals and thanks them for their time and effort in getting this document revised. Christina Sames Ali Quraishi, Staff Executive Vice Presid

21、ent Engineering Services Director Operations and Engineering Operations and Engineering v FOREWORD This report is published to foster consensus among parties conducting energy-based measurement of natural gas. The report addresses methods, assumptions and criteria relevant to the determination of he

22、ating value and heat energy. Gas property measurement has a history of continual refinement. A goal of this report is to provide stabilizing influence through the stewardship of the Transmission Measurement Committee of the American Gas Association. This revision was triggered by technology advancem

23、ent and heightened industry attention to gas quality issues. This version of AGA Report No. 5 supersedes all prior versions of this document. Users of previous editions are advised to upgrade to this edition. Programs in Excel Spreadsheet for AGA 5 related calculations including heating values both

24、in Imperial and SI units are provided with this report. vi TABLE OF CONTENTS DISCLAIMER AND COPYRIGHT III ACKNOWLEDGEMENTS IV FOREWORD . V TABLE OF CONTENTS VI 1. SCOPE OF APPLICATION . 1 1.1 General . 1 1.2 Range Of Application 1 1.2.1 Inclusion Criteria for Fuel Gas Mixtures 1 1.3 Range of Gas Mix

25、ture Constituents . 2 1.3.1 Concentration of Gas Constituents 2 1.3.2 Directly Supported Constituents 2 1.3.3 Other Constituents . 3 1.3.4 Grouped Constituents 3 1.4 Other Composition-Dependent Gas Properties 4 1.5 Range of Contract Base Pressures and Contract Base Temperatures 4 1.6 Compounds in th

26、e Liquid State 4 2. DEFINITIONS AND BACKGROUND . 5 2.1 British Thermal Unit (Btu). 5 2.2 Calorie 5 2.3 Combustion 5 2.4 Combustion Reference Temperature . 7 2.5 Contract Base Conditions 8 2.6 Dekatherm 8 2.7 Dry Gas 8 2.8 Higher Heating Value (HHV), also known as Gross Heating Value (GHV) . 8 2.9 Id

27、eal Gas 8 2.10 Motor Octane Number (MON) 9 2.11 Methane Number (MN) . 9 2.12 Natural Gas Energy Measurement . 9 2.13 Lower Heating Value (LHV), also known as Net Heating Value (NHV) . 9 2.14 Real Gas . 9 2.15 Relative Density and Specific Gravity . 10 2.16 Sensible Heat . 10 2.17 Therm . 10 2.18 Wat

28、er Dew Point 10 2.19 Water-Saturated and Partially Water-Saturated Gases 10 2.20 Wobbe Number (WN), also known as Wobbe Index (WI) 11 3. BASIS FOR CUSTODY TRANSFER . 12 3.1 Specification of Energy . 12 3.2 Specification of Heating Value 12 3.3 Higher (Gross) Versus Lower (Net) Heating Value 12 3.4 D

29、ry Versus Saturated Heating Value . 12 3.5 Energy Derived from Volumetric Measurements 13 3.6 Energy Derived from Mass Measurements 13 3.7 Sampling and Off-line Analysis . 13 3.8 Compressibility Factor . 13 3.9 Enthalpy . 14 3.10 Accounting for the Presence of Water . 14 vii 4. UNCERTAINTY 16 4.1 Ac

30、ceptance Criteria 16 5. HEATING VALUE DETERMINATION METHODS 17 5.1 Heating Value from Gas Composition . 17 5.1.1 General Requirements . 17 5.1.2 Gas Chromatography 17 5.1.3 Mass Spectrometry 17 5.2 Heating Value Measurement 17 5.2.1 General Requirements . 17 5.2.2 Calorimeter 17 5.2.3 Fuel/Air Titra

31、tion 18 5.3 Heating Value from Inferential (Correlative) Methods . 18 6. REFERENCES. 19 APPENDIX A A-1 Pre-Calculated Tables of Ideal Gas Gross Heating Value (Volumetric Basis) . A-2 Pre-Calculated Tables of Ideal Gas Gross Heating Value (Mass Basis) . A-4 Example Calculation of Volumetric Heating V

32、alue (Imperial units) A-6 Example Calculation of Volumetric Heating Value (SI Units) . A-8 Standard Enthalpies of Formation . A-10 Stoichiometric Coefficients . A-11 Balanced Combustion Reaction Equations for Common Hydrocarbons A-12 Ideal Gas Molar Heating Values at 298.15 K . A-12 Enthalpy of Vapo

33、rization of Water . A-13 Enthalpy Adjustment . A-13 Equation Constants for the Ideal Gas Heat Capacity Correlation . A-15 Calculation of Summations Factors A-16 Equation Constants for 2ndVirial Coefficients A-18 Summation Factors at Common Reference Temperatures A-19 Molar Masses A-21 Table of H/C (

34、Hydrogen to Carbon) Ratios A-22 Example Process for Supporting Additional Compounds . A-23 Calculating Natural Gas Relative Density and the Compressibility of Air . A-26 Estimation of Water Content from Dew Point Measurements A-28 Dew Point Temperature Versus Water Content in Natural Gas A-29 APPEND

35、IX B B-1 FORM FOR PROPOSALS ON AGA REPORT NO. 5, MARCH 2009 . B-1 1 1. Scope of Application 1.1 General This report applies specifically to energy-based custody transfer measurement of natural gas. It may or may not be suitable to other applications, as determined by the user. Heating value measurem

36、ent is used in tandem with volume flow or mass flow measurement, the use of which is guided by other reports and industry standards. This report is not intended to supersede, extend or duplicate the content of flow measurement documents. For ease of use, this report supports two approaches to estima

37、ting heating value from composition: simplified table look-up or full calculation. The approaches are functionally equivalent because the look-up tables were produced with the calculation methods. The tables A.1.1 and A.1.2 provide pre-calculated heating values of common gas constituents for a range

38、 of common reference conditions. The detailed methods and data elsewhere in this report are primarily for traceability. Report No. 5 differs in scope from other documents concerning energy measurement. In addition to technical data and formulas, this report recommends performance criteria. The physi

39、cal property data reproduced in this report were drawn from widely-accepted industry sources, including NIST1 and CODATA12. Results obtained using this report will agree closely with results from methods sharing its lineage. In keeping with gas industry practice, this report supports both SI and Imp

40、erial units of measure. 1.2 Range Of Application This report is focussed on methods for predicting the heat energy resulting from complete combustion of commercially acceptable natural gas. 1.2.1 Inclusion Criteria for Fuel Gas Mixtures This report is valid only for fuel gas mixtures meeting the fol

41、lowing criteria: the fuel must be in the gas phase at the specified reference conditions. air/fuel mixtures must be capable of ignition followed by self-sustaining, exothermic combustion reactions. hydrocarbon combustion reactions must reach stoichiometric completion, resulting in product water and

42、carbon dioxide. trace products of combustion, such as NOx and CO, are negligible in the context of heat production Not in the scope of this report are: combustion characteristics such as flame geometry and air/fuel ratio determination of emissions or the products of incomplete combustion natural Gas

43、 Interchangeability indices, other than Wobbe Number, Methane Number (MN) and Motor Octane Number (MON) 2 1.3 Range of Gas Mixture Constituents 1.3.1 Concentration of Gas Constituents The maximum proportion or concentration of constituents within a mixture is limited only by the criteria given in se

44、ction 1.2.1. 1.3.2 Directly Supported Constituents The gas mixture constituents directly supported by this report are: Methane Ethane Propane Isobutane (iC4) and Normal Butane (nC5) Isopentane (iC5) and Normal Pentane (nC5) Normal Hexane (nC6) Normal Heptane (nC7) Normal Octane (nC8) Normal Nonane (

45、nC9) Normal Decane (nC10) Hydrogen (H2) Hydrogen Sulfide (H2S) Oxygen (O2) Water (H2O) Carbon Dioxide (CO2) Carbon Monoxide (CO) Nitrogen (N2) Helium (He) Argon (Ar) 2,2-Dimethyl Propane 2-Methyl Pentane 3-Methyl Pentane 2,2-Dimethyl Butane 2,3-Dimethyl Butane Ethylene Propylene Methyl Alcohol 3 1.3

46、.3 Other Constituents The methods of this report may also be applicable to other potential gas constituents if the following parameters are available: compound molar mass enthalpy of formation at 25 C (77 F) second virial coefficient or summation factor at the temperature of interest stoichiometric

47、coefficients calculation parameters for ideal gas heat capacity 1.3.4 Grouped Constituents In the context of energy measurement, it is possible to characterize some compounds as constituents of a group rather than as individual constituent. A group of compounds may be thought of as a pseudo-compound

48、 whose properties are inferred from those of its members. For example, the pseudo-compound C6+ represents the sum of all hydrocarbons whose carbon number is 6 and higher. Typically, C6+ represents pre-determined proportions of nC6, nC7and nC8. A number of default proportions are widely used but none

49、 are mandated. The following two examples illustrate the sensitivity of heating value to assumed proportions within C6+. The Amarillo example gas listed in AGA Report No. 8 (2ndedition) includes 0.0393 mole percent of normal C6. The calculated gross heating value of the mixture is 1034.8 Btu per cubic foot at 14.73 psia and 60 F. For comparison, assume the mixture contains C6+ with 60/30/10 proportions. Upon recalculation, the heating value is higher by 0.015% (1035.0