32
Z 8767 : 2006 (ISO/DIS 9300 : 2003)
参考文献
ISO文書
[1] ISO/TR 5168 Measurement of fluid flow−Evaluation of uncertainties
CFVNの一般的事項
[2] K.E. STARLING, J. L. SAVIDGE. Compressibility factors for natural gas and related hydrocarbon gases.
Second edition, Transmission Measurement Committee Report No.8. AGA November 1992, also Errata N°1
issued by AGA June 1993
[3] JAESCHKE, M., AUDIBERT, S., VAN CANEGHEM, P., HUMPHREYS, A. E., JANSSEN-VAN
ROSMALEN, R., PELLEI, Q., MHICHELS, J.P.J., SCHOUTEN, J. A., TEN SELDAM, C. A;, High accuracy
compressibility factor calculation for natural gases and similar mixtures by use of a truncated virial equation,
GERG Technical Monograph TM2 (1988), and Fortschritt-Berichte VDI, Series 6, N°231 (1989)
[4] R.C.JOHNSON. Real gas effects in critical flow through nozzles and tabulated thermodynamic properties.
NASA TN D-2565 (1965)
[5] R.C. JOHNSON. Tables of critical flow functions and thermodynamic properties for methane and
computational procedures for both methane and natural gas. NASA SP-3074, Lewis Research Center, 1972
[6] STEWART, D.G., WATSON, J.T.R., VAIDYA, A.M. Uncertainty in the theoretical mass flow-rate of pure
gases through Critical Flow Nozzles. Int. Fluid Flow Measurement Symposium, Denver 27-30 June, 1999
[7] STEWART, D.G., WATSON, J.T.R., VAIDYA, A.M. The effect of using atmospheric air in Critical Flow
Nozzles. Int. Fluid Flow Measurement Symposium, Denver 27-30 June, 1999
[8] KEGEL, T. A study of the repeatability and reproducibility of the Critical Flow Nozzle. Int. Fluid Flow
Measurement Symposium, Denver 27-30 June, 1999
[9] CARON, R.W., BRITTON, C.L., KEGEL, T. Investigation into the accuracy of multiple Critical Flow Venturis
mounted in parallel within a common plenum. Int. Fluid Flow Measurement Symposium, Denver 27-30 June,
1999
[10] PARK, K.A., CHOI, Y.M., CHOI, H.M., CHA, T.S. YOON, B.H. The evaluation of critical pressure ratios of
sonic nozzle at low Reynolds numbers, released for Flow. Meas. Instrum
[11] STUDZINSKI, W.,WILLIAMSON, I.D., JUNGOWSKI, W., BOTROS, K.K., SAWCHUK, B., STROM, V.,
Novas gravimetric meter prover and sonic nozzle facility, CGA Gas Measurement School, Alberta, Canada,
1994
[12] CHOI, Y.M., PARK, K.A., PARK S.O. Interference effects between sonic nozzles, Flow. Meas. Instrum. 8,
page 113-119, 1997
[13] CHOI, Y.M., PARK, K.A., PARK, J.T., CHOI, H. M., PARK S.O. Interference effects of three sonic nozzles of
different throat diameters in the same meter tube, Flow. Meas. Instrum. 10, page 175-181, 1999
[14] ISHIBASHI, M., TAKAMOTO, Theorical discharge coefficient of a critical circular-arc nozzle with laminar
boundary layer and its verification by measurements using super-accurate nozzles, Flow Measurement and
Instrumentation 11, 305/313, 2000
――――― [JIS Z 8767 pdf 36] ―――――
33
Z 8767 : 2006 (ISO/DIS 9300 : 2003)
[15] von LAVANTE, E., NATH, B., DIETRICH, H., Effects of instabilities on flow rates in small sonic nozzles,
9th Conference on Flow Measurement FLOMEKO98, Lund, 1998
[16] CARON, R.W., BRITTON, C.L., KEGEL, T., Investigation into the premature unchocking phenomena of
critical flow venturis, Proceedings of ASME FEDSM 2000-11108, Boston, June 2000
トロイダルスロートベンチュリノズルの流出係数
[17] BRAIN, T. J. S. and MacDONALD, L. M. Evaluation of the performance of small-scale critical flow venturi
using the NEL gravimetric gas flow standard test facility. Fluid Flow Measurement in the Mid 1970s.
Edinburgh: HMSO, 1977, pp. 103-125
[18] BRAIN, T. J. S. and REID, J. Primary calibration of critical flow venturis in high-pressure gas. Flow
Measurement of Fluids, edited by DIJSTELBERGEN, H. H. and SPENCER, E. A. Amsterdam: North Holland
Publishing, 1978, pp. 54-64
[19] SMITH, R. E. and MATZ, R. J. A theoretical method of determining discharge coefficients for Venturis
operating at critical flow conditions. J. Bas. Engng., 1962, vol. 84, No. 4, pp. 434-446
[20] ARNBERG, B. T., BRITTON, C. L. and SEIDL, W. F. Discharge coefficient correlations for circular arc
venturi flowmeters at critical (sonic) low. Paper No. 73-WA/FM-8. New York: American Society of
Mechanical Engineers, 1973
[21] BRAIN, T. J. S. and REID, J. An investigation of the discharge coefficient characteristics and manufacturing
specification of toroidal inlet critical flow venturi nozzles proposed as standard ISO flowmeters. Proceedings
of the International Conference on Advances in Flow Measurement, Paper C1, University of Warwick.
Cranfield, Bedford: BHRA Fluid Engineering, 1981
[22] SPENCER, E. A., EUJEN, E., DIJSTELBERGEN, H. H. and PEIGNELIN, G. Intercomparison campaign on
high pressure gas flow test facilities. EEC Document No. EUfR 6662. Brussels-Luxembourg: ECSC-EEC-
EAEC, 1980
[23] U.KARNIK, E.B.BOWLES, J.BOSIO, S.CALDWELL. North American Inter-Laboratory Flow Measurement
Testing Program. North Sea Flow Measurement Workshop 1996−Peebles, Scotland. Paper no. 3
[24] M.ISHIBASHI, M.TAKAMOTO. Very Accurate Analytical Calculation of the Discharge Coefficients of
Critical Venturi Nozzles with Laminar Boundary Layer. FLUCOME97, Hayama
[25] ISHIBASHI, M., TAKAMOTO, M. Discharge coefficient of superaccurate critical nozzle at pressurised
condition. Int. Fluid Flow Measurement Symposium, Denver 27-30 June, 1999
[26] ARNBERG B.T. and ISHIBASHI M., Discharge coefficient equations for critical flow toroidal throat venturi
nozzles, Proceedings of ASME FEDSM01-18030, ASME New Orleans, May 2001
[27] ISHIBASHI, M., TAKAMOTO, M. Discharge coefficient of superaccurate critical nozzle accompanied with
the boundary layer transition measured by reference super-accurate critical nozzles connected in series.
Proceedings of ASME FEDSM01-18036, ASME New Orleans, May 2001
シリンドリカルスロートベンチュリノズルの流出係数
[28] GRENIER, P. Discharge coefficients of cylindrical nozzles used in sonic conditions. NEL fluid Mechanics
Silver Jubilee Conference, Paper No. 1.2. East Kilbride, Glasgow: National Engineering Laboratory,
November 1979
――――― [JIS Z 8767 pdf 37] ―――――
34
Z 8767 : 2006 (ISO/DIS 9300 : 2003)
[29] PEIGNELIN, G. and BENZONI, A. Utilisation des Venturi tuyres fonctionnant en rgime d'coulement
sonique comme talons de dbits de gaz sous pression. Note dc Gaz de France, no 67842, 1967
[30] PEIGNELIN, G. and GRENIER, P. Etude du coefficient do dcharge des tuyeres fonctionnant en regime
d'ecoule ment sonique au col utilises comme talon pour le mesurage de dbit de gaz sous pression. Congrs
de I'Association technique du gaz en France, 1978
[31] GRENIER, P. Etude statistique du coefficient de dcharge des tuyres a col cylindrique fonctionnant en rgime
sonique. Note du Gaz de France, n°81474, August 1981
[32] SPENCER, E. A., EUJEN, E., DIJSTELBERGEN, H. H. and PEIGNELIN, G. Intercomparison campaign on
high pressure gas flow test facilities. EEC Document No. EW 6662. Brussels-Luxembourg: ECSC-EEC-EAEC,
1980
[33] J.BOSIO, J.F.CABROL, P.KERVEVAN. Intercomparison of the calibration results obtained at Gaz de France
Alforville and K-Lab on a critical flow Venturi nozzle. FLOMEL'94. Glasgow, Scotland
[34] VULOVIC, F. Report on the intercomparison carried out on eight European benches using a sonic nozzle as
transfer standard. EUROMET PROJECT No. 307. - M.CERMAP VUL/SZ 97/I/129, 1997
[35] VULOVIC, F., VINCENDEAU, E., VALLET, J.P., WINDENBERGER, C., VILLANGER, O., BOSIO, J.
Influence of the thermodynamics calculations on the flow rate of sonic nozzles. Int. Fluid Flow Measurement
Symposium, Denver 27-30 June, 1999
附属書文献
[36] Stewart D.G., Watson J.T.R., and Vaidya A.M. Improved critical flow factors and representative equations for
four calibration gases. Flow Measurement and Instrumentation,1999; 10(1): 27-34
[37] Span R., Lemmon E.W., Jacobsen R.T., and Wagner W. A Reference Quality Equation of State for Nitrogen.
International Journal of Thermophysics, 1998; 19(4): 1121-1132
A new equation of state for argon covering the fluid region from the
[38] Tegeler Ch., Span R., and Wagner W.
triple-point temperature to 700 K at pressures up to 1000 MPa.Paper Presented at 13th Symposium on
Thermophysical Properties, Boulder, June 1997
[39] Panasati M.D., Lemmon E.W., Penoncello S.G., Jacobsen R.T., and Friend D.G.Thermodynamic properties of
air from 60 to 2000 K at pressures up to 2000 MPa. Paper Presented at 13th Symposium on Thermophysical
Properties, Boulder, June 1997
A new equation of state and tables of thermodynamic properties for methane
[40] Setzmann U. and Wagner W.
covering the range from the melting line to 625 K at pressures up to 1000 MPa. Journal of Physical and
Chemical Reference Data, 1991; 20(6): 1061-1116
A New Equation of State for Carbon Dioxide Covering the Fluid Region from the
[41] Span R. and Wagner W.
Journal of Physical and Chemical
Triple-Point Temperature to 1100 K at Pressures up to 800 MPa.
Reference Data, 1996; 25(6): 1509-1596
Flow measurement engineering handbook.
[42] Miller RW. McGraw-Hill, 1983
[43] IAPWS Formulation 1995 for the Thermodynamic Properties of Ordinary Water Substance for General and
IAPWS, 1996
Scientific Use.
A new correlation for the critical mass flux of natural
[44] Stewart D.G., Watson J.T.R., and Vaidya A.M.
mixtures. Flow Measurement and Instrumentation, Volume 11 Number 4, December 2000
――――― [JIS Z 8767 pdf 38] ―――――
35
Z 8767 : 2006 (ISO/DIS 9300 : 2003)
The effect of using atmospheric air in critical flow
[45] Stewart D.G., Watson J.T.R., and Vaidya A.M.
nozzles. Paper presented at the 4th International Symposium on Fluid Flow Measurement, Denver,
une 1999
The effect of high beta values on mass flow through critical
[46] Stewart D.G., Watson J.T.R., and Vaidya A.M.
flow nozzles Flow Measurement and Instrumentation, Volume 11 Number 4, December 2000
JIS Z 8767:2006の引用国際規格 ISO 一覧
- ISO/DIS 9300:2003(IDT)
JIS Z 8767:2006の国際規格 ICS 分類一覧
- 17 : 度量衡及び測定.物理的現象 > 17.120 : 流量の測定 > 17.120.10 : 閉水路における流れ