Gas retention and release behavior in Hanford double-shell waste tanks

Meyer, Philip D.; Brewster, M.E.; Bryan, Samuel A.

doi:10.2172/527909

Cited by 39 publications

(128 citation statements)

References 15 publications

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“…Average BD GRE volumes for the six BD positive tanks are reported in Meyer et al (1997). These values were compared with the mean (average) of the spontaneous BD GRE release volumes calculated for 200 trials in Resolve.…”

Section: "Filterresolveresultssh" Version 12 (Mccomak 1999)mentioning

confidence: 99%

“…Historical monitoring data or values inferred from monitoring data are available for the BD GRE behavior of some tanks. These data include the following: Model predictions for average BD GRE volume, the average peak hydrogen concentration after a release, and average period between BD GREs were compared against the monitoring data (Meyer et al 1997, Stewart 1998) for double-shell tanks (DSTs) in which BD GRE behavior has historically been observed. In addition, the AT'S evaluation of BD GRE potential-whether BD behavior will or will not occur in a tank-was compared to the list of tanks in which BD GRE behavior has historically been observed.…”

Section: Validation: Buoyant Displacement Gas Release Event Modelmentioning

confidence: 99%

“…References and Inputs: Gas Retention and Release Behavior in Hanford Double-Shell Waste Tanks (Meyer et al 1997). "shmsgred.xls" (Stewart 1998), a spreadsheet containing monitoring data and derivation of peak hydrogen concentration for tanks with observed buoyant displacement GRE behavior.…”

Section: Flammable Gas Safety Analysis Data Reviewmentioning

confidence: 99%

“…These values were removed electronically from the debug output file using the "FilterResolveResults.sh' (McCornak 1999) filter tool. Meyer et al (1997) reports average BD GRE periods as well. These were compared to the spontaneous BD GRE frequencies reported in the GUI calculated statistics.…”

Section: -4mentioning

confidence: 99%

“…Except for the Tank 241-SY-101 analysis, the average of Resolve-calculated BD GRE release volumes for a tank vary from the average of BD GRE volumes inferred from headspace hydrogen measurement histories for the same tank (Meyer et al 1997) by no more than a factor of 2 (Table 4-1 1). This is within the acceptable range for this comparison.…”

Section: Bd Gre Volumementioning

confidence: 99%

See 4 more Smart Citations

Flammable Gas Refined Safety Analysis Tool Software Verification and Validation Report for Resolve Version 2.5

Bratzel¹

2000

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Section: "Filterresolveresultssh" Version 12 (Mccomak 1999)mentioning

confidence: 99%

Section: Validation: Buoyant Displacement Gas Release Event Modelmentioning

confidence: 99%

Section: Flammable Gas Safety Analysis Data Reviewmentioning

confidence: 99%

Section: -4mentioning

confidence: 99%

Section: Bd Gre Volumementioning

confidence: 99%

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Flammable Gas Refined Safety Analysis Tool Software Verification and Validation Report for Resolve Version 2.5

Bratzel¹

2000

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Rayleigh-Taylor Instability within Sediment Layers Due to Gas Retention: Preliminary Theory and Experiments

Gauglitz¹,

Wells²,

Buchmiller³

et al. 2013

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Executive SummaryIn Hanford underground waste storage tanks, a typical waste configuration is settled beds of solid particles beneath liquid layers. The settled beds are typically also composed of layers, and these layers can have different physical and chemical properties. One postulated configuration within the settled bed is more-dense layer lying atop a less-dense layer. The different densities can be a result of different gas retention in the layers (Meacham and Kirch 2013) or different degrees of settling and compaction in the layers. This configuration can experience a Rayleigh-Taylor (RT) instability, in which the less-dense lower layer rises into the upper layer. Previous studies of gas retention and release have not considered potential buoyant motion within a settled bed of solids.The purpose of this report is to provide a review of the literature on RT instabilities with an emphasis on studies that are pertinent to RT instabilities between two solid materials of different bulk density that are formed from settled slurries. A preliminary evaluation of the potential for different gas retention in a sediment layer and gas release from the potential buoyant motion are also discussed, and the results of preliminary experiments that demonstrate RT instabilities due to gas retention are summarized.Several studies provide useful theoretical and experimental results that can be used to estimate the difference in void fraction (or in bulk density) between two layers that will result in instability within tanks, as well as the effects of yield stress and tank diameter. For soft solids (such as waste slurries), experiments have only been conducted with a slurry layer above a gas layer; experiments with two solid layers will be needed to support the stability criterion developed from the literature data. Evaluations of configurations with more than two layers that have different bulk densities were not available in the literature; however, configurations with multiple-layer systems are expected to be more stable than two layers with the same total difference in bulk density.Measurements of gas void fractions in slurries in Hanford double-shell waste tanks, when combined with density measurements of de-gassed samples, identified examples in which the gas void fraction increases with depth, and the bulk density (including gas) decreases with depth, showing that that there is a potential for buoyant motion within waste sediment layers arising from differences in bulk density.Observations of bubble retention in experiments that had gas release pathways, which were generally filled with gas, did not show a noticeable difference in gas retention above and below the depth of an open gas channel. This suggests that gas retention may not necessarily increase below the maximum channel depth. Additional experiments would be required to confirm or refute this observation.An increase in yield stress (i.e., a stronger material) would be expected to decrease the amount of gas release caused by buoyant motion within a sediment l...

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Prediction of Peak Hydrogen Concentrations for Deep Sludge Retrieval in Tanks AN-101 and AN-106 from Historical Data of Spontaneous Gas Release Events

Wells¹,

Cooley²

2013

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Gas retention and release behavior in Hanford double-shell waste tanks

Cited by 39 publications

References 15 publications

Flammable Gas Refined Safety Analysis Tool Software Verification and Validation Report for Resolve Version 2.5

Flammable Gas Refined Safety Analysis Tool Software Verification and Validation Report for Resolve Version 2.5

Rayleigh-Taylor Instability within Sediment Layers Due to Gas Retention: Preliminary Theory and Experiments

Prediction of Peak Hydrogen Concentrations for Deep Sludge Retrieval in Tanks AN-101 and AN-106 from Historical Data of Spontaneous Gas Release Events

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