ASME MFC 7M 1987 R2014
$98.04
ASME MFC-7M Measurement of Gas Flow by Means of Critical Flow Venturi Nozzles – Reaffirmed: 2014
| Published By | Publication Date | Number of Pages |
| ASME | 1987 | 38 |
This Standard applies only to the steady flow of single-phase gases and deals with devices for which direct calibration experiments have been made, sufficient in number and quantity to enable inherent systems of applications to be based on their results and coefficients to be given with certain predictable limits of uncertainty. The critical flow venturi nozzles dealt with can only be used within limits that are specified, for example nozzle throat to inlet diameter ratio and Reynolds number. This Standard specifies the geometry and method of use (installation and operating conditions) of critical flow venturi nozzles inserted in a system to determine the mass flow rate of the gas flow rate of the gas flowing through the system. It also gives necessary information for calculating the flow rate and its associated uncertainty. This Standard applies only to venturi nozzles in which the flow is critical. Critical flow exists when the mass flow rate through the venturi nozzle is the maximum possible for the existing upstream conditions. At critical flow or choked conditions, the average gas velocity at the nozzle throat closely approximates the local sonic velocity. Information is given in this Standard for cases in which: (a) the pipeline upstream of the venturi nozzle is of circular cross section; or (b) it can be assumed that there is a large space upstream of the venturi nozzle. The venturi nozzles specified in this Standard are called primary devices. Other instruments for the measurement are known as secondary devices. This Standard covers primary devices; secondary devices will be mentioned only occasionally.
PDF Catalog
| PDF Pages | PDF Title |
|---|---|
| 3 | Foreword |
| 4 | Standards Committee Roster |
| 6 | CONTENTS |
| 8 | 1 Scope and Field of Application 2 Symbols and Definitions 2.1 Symbols 2.2 Definitions |
| 9 | Table 1 Symbols |
| 12 | 3 Basic Equations 3.1 State Equation 3.2 Flow Rate in Ideal Conditions 3.3 Flow Rate in Real Conditions 4 Applications For Which the Method is Suitable |
| 13 | 5 Standard Critical Flow Venturi Nozzles 5.1 General Requirements 5.2 Standard Venturi Nozzles |
| 14 | Figures 1 Toroidal Throat Venturi Nozzle |
| 15 | 6 Installation Requirements 6.1 General 6.2 Upstream Pipeline 6.3 Large Upstream Space 6.4 Downstream Requirements 6.5 Pressure Measurement 2 Cylindrical Throat Venturi Nozzle |
| 16 | 3 Installation Requirements for an Upstream Pipework Configuration 4 Detail of Pressure Tap |
| 17 | 6.6 Drain Holes 6.7 Temperature Measurement 6.8 Density Measurement 7 Calculation Methods 7.1 Method of MassFlow Rate Computation 7.2 Discharge Coefficient |
| 18 | 7.3 Computation of Real Gas Critical Flow Function 7.4 Conversion of Measured Pressure and Temperature to Stagnation Conditions 7.5 Maximum Permissible Downstream Pressure 8 Uncertainties in the Measurement of Flow Rate |
| 19 | 5 Maximum Permissible Back Ratio for Critical Flow Venturi Nozzles |
| 20 | Appendices A Venturi Nozzle Discharge Coefficients Tables A1 Toroidal Throat Venturi Nozzle Discharge Coefficient A2 Cylindrical Throat Venturi Nozzle Discharge Coefficient |
| 21 | A3 Comparison of Theoretical and Experimental Discharge Coefficients for the Toroidal Throat Nozzle |
| 22 | B References from Which Standard Critical Flow Venturi Nozzle Discharge Coefficients Were Obtained |
| 23 | C Example Flow Calculation Figure C1 Sectional View of the Nozzle and Pipe |
| 30 | D Critical Flow Functions |
| 32 | E The Critical Flow Coefficient |
| 35 | E1 Table of Fluids for Various Equations of State |
| 36 | E2 Critical Flow Coefficient for Nitrogen E3 Critical Flow Coefficient for Oxygen E4 Critical Flow Coefficient for Argon |
| 37 | E5 Critical Flow Coefficient for Methane E6 Critical Flow Coefficient for Carbon Dioxide |
