Abstract
The presentation summarises the highlights of experimental results obtained for VVER type horizontal steam generator heat transfer, primary side flow pattern, and mixing in the hot collector during secondary side boil-off with primary at single-phase natural circulation. The experiments were performed using the PACTEL facility with Large Diameter (LD) steam generator models, with collector instrumentation designed specifically for these tests. The key findings are as follows: (1) the primary to secondary heat transfer degrades as the secondary water inventory is depleted, following closely the wetted tube area; (2) a circulatory flow pattern exists in the tube bundle, resulting in reversed flow (from cold to the hot collector) in the lower part of the tube bundle, and continuous flow through the upper part, including the tubes that have already dried out; and (3) mixing of the hot leg flow entering the hot collector and reversed, cold, tube flow remains confined within the collector itself, extending only a row or two above the elevation at which tube flow reversal has taken place. 6 refs.
Hyvaerinen, J;
[1]
Kouhia, J
[2]
- Finnish Centre for Radiation and Nuclear Safety, Helsinki (Finland)
- VTT Energy, Lappeenranta (Finland)
Citation Formats
Hyvaerinen, J, and Kouhia, J.
Experimental verification of the horizontal steam generator boil-off transfer degradation at natural circulation.
Finland: N. p.,
1997.
Web.
Hyvaerinen, J, & Kouhia, J.
Experimental verification of the horizontal steam generator boil-off transfer degradation at natural circulation.
Finland.
Hyvaerinen, J, and Kouhia, J.
1997.
"Experimental verification of the horizontal steam generator boil-off transfer degradation at natural circulation."
Finland.
@misc{etde_605568,
title = {Experimental verification of the horizontal steam generator boil-off transfer degradation at natural circulation}
author = {Hyvaerinen, J, and Kouhia, J}
abstractNote = {The presentation summarises the highlights of experimental results obtained for VVER type horizontal steam generator heat transfer, primary side flow pattern, and mixing in the hot collector during secondary side boil-off with primary at single-phase natural circulation. The experiments were performed using the PACTEL facility with Large Diameter (LD) steam generator models, with collector instrumentation designed specifically for these tests. The key findings are as follows: (1) the primary to secondary heat transfer degrades as the secondary water inventory is depleted, following closely the wetted tube area; (2) a circulatory flow pattern exists in the tube bundle, resulting in reversed flow (from cold to the hot collector) in the lower part of the tube bundle, and continuous flow through the upper part, including the tubes that have already dried out; and (3) mixing of the hot leg flow entering the hot collector and reversed, cold, tube flow remains confined within the collector itself, extending only a row or two above the elevation at which tube flow reversal has taken place. 6 refs.}
place = {Finland}
year = {1997}
month = {Dec}
}
title = {Experimental verification of the horizontal steam generator boil-off transfer degradation at natural circulation}
author = {Hyvaerinen, J, and Kouhia, J}
abstractNote = {The presentation summarises the highlights of experimental results obtained for VVER type horizontal steam generator heat transfer, primary side flow pattern, and mixing in the hot collector during secondary side boil-off with primary at single-phase natural circulation. The experiments were performed using the PACTEL facility with Large Diameter (LD) steam generator models, with collector instrumentation designed specifically for these tests. The key findings are as follows: (1) the primary to secondary heat transfer degrades as the secondary water inventory is depleted, following closely the wetted tube area; (2) a circulatory flow pattern exists in the tube bundle, resulting in reversed flow (from cold to the hot collector) in the lower part of the tube bundle, and continuous flow through the upper part, including the tubes that have already dried out; and (3) mixing of the hot leg flow entering the hot collector and reversed, cold, tube flow remains confined within the collector itself, extending only a row or two above the elevation at which tube flow reversal has taken place. 6 refs.}
place = {Finland}
year = {1997}
month = {Dec}
}