Abstract
Choked flow mechanism, characteristics of two-phase flow sound velocity and compressibility effects on flow through various piping system components are studied to develop analysis methodology for high pressure two-phase choked flow in complex piping system which allows choking flow rate evaluation and piping system design related analysis. Piping flow can be said choked if Mach number is equal to 1 and compressibility effects can be accounted through modified incompressible formula in momentum equation. Based on these findings, overall analysis system is developed to study thermal-hydraulic effects on steady-state piping system flow and future research items are presented. (Author).
Yoo, Geun Jong;
Sim, Yoon Sub;
Chung, Chang Kyu;
Lee, Jun
[1]
- Korea Atomic Energy Res. Inst., Taejon (Korea, Republic of)
Citation Formats
Yoo, Geun Jong, Sim, Yoon Sub, Chung, Chang Kyu, and Lee, Jun.
Development of high pressure two-phase choked flow analysis methodology in complex piping system.
Korea, Republic of: N. p.,
1992.
Web.
Yoo, Geun Jong, Sim, Yoon Sub, Chung, Chang Kyu, & Lee, Jun.
Development of high pressure two-phase choked flow analysis methodology in complex piping system.
Korea, Republic of.
Yoo, Geun Jong, Sim, Yoon Sub, Chung, Chang Kyu, and Lee, Jun.
1992.
"Development of high pressure two-phase choked flow analysis methodology in complex piping system."
Korea, Republic of.
@misc{etde_10111423,
title = {Development of high pressure two-phase choked flow analysis methodology in complex piping system}
author = {Yoo, Geun Jong, Sim, Yoon Sub, Chung, Chang Kyu, and Lee, Jun}
abstractNote = {Choked flow mechanism, characteristics of two-phase flow sound velocity and compressibility effects on flow through various piping system components are studied to develop analysis methodology for high pressure two-phase choked flow in complex piping system which allows choking flow rate evaluation and piping system design related analysis. Piping flow can be said choked if Mach number is equal to 1 and compressibility effects can be accounted through modified incompressible formula in momentum equation. Based on these findings, overall analysis system is developed to study thermal-hydraulic effects on steady-state piping system flow and future research items are presented. (Author).}
place = {Korea, Republic of}
year = {1992}
month = {Dec}
}
title = {Development of high pressure two-phase choked flow analysis methodology in complex piping system}
author = {Yoo, Geun Jong, Sim, Yoon Sub, Chung, Chang Kyu, and Lee, Jun}
abstractNote = {Choked flow mechanism, characteristics of two-phase flow sound velocity and compressibility effects on flow through various piping system components are studied to develop analysis methodology for high pressure two-phase choked flow in complex piping system which allows choking flow rate evaluation and piping system design related analysis. Piping flow can be said choked if Mach number is equal to 1 and compressibility effects can be accounted through modified incompressible formula in momentum equation. Based on these findings, overall analysis system is developed to study thermal-hydraulic effects on steady-state piping system flow and future research items are presented. (Author).}
place = {Korea, Republic of}
year = {1992}
month = {Dec}
}