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Controlling Dissolved Oxygen, Iron and Manganese in Water-Supply Reservoirs using Hypolimnetic OxygenationGantzer, Paul Anthony 23 April 2008 (has links)
Hypolimnetic oxygenation systems, such as linear bubble-plume diffusers, are used to improve raw water quality. Linear bubble-plume diffusers were installed in Spring Hollow Reservoir (SHR) and Carvins Cove Reservoir (CCR). Diffusers induce mixing that aids distribution of oxygen throughout the hypolimnion. The induced mixing also creates an undesirable effect by increasing hypolimnetic oxygen demand (HOD). Nevertheless, oxygenation systems are commonly used and long-term oxygenation is hypothesized to actually decrease HOD. Increased oxygen concentrations in combination with the induced mixing affect the location of the oxic/anoxic boundary relative to the sediment water interface. If the oxic/anoxic boundary is pushed beneath the sediment/water interface, the concentrations of soluble iron and manganese in the bulk water are reduced.
This work was performed to further validate a recently published bubble-plume model that predicts oxygen addition rates and the elevation in the reservoir where the majority of the oxygen is added. Also, the first field observations of a theoretically expected secondary plume are presented. Model predicted addition rates were compared to observed accumulation rates to evaluate HOD over a wide range of applied gas flow rates. Observations in both reservoirs showed evidence of horizontal spreading that correlated well with plume-model predictions and of vertical spreading below diffuser elevations, showing oxygen penetration into the sediment. Experimental observations of a theoretically expected secondary plume structure also correlated well with model predictions. Plume-induced mixing was shown to be a function of applied gas flow rates, and was observed to increase HOD. HOD was also observed to be independent of bulk hypolimnion oxygen concentration, indicating that the increase in oxygen concentration is not the cause of the increased HOD. Long-term oxygenation resulted in an overall decrease in background HOD as well as a decrease in induced HOD during diffuser operation. Elevated oxygen concentrations and mixing, which occur naturally during destratification and artificially during oxygenation, were observed to coincide with low dissolved metal concentrations in CCR. Movement of the oxic/anoxic boundary out of the sediment, which is also common during stratified periods, appears to facilitate transport of reduced Mn to the overlying waters. Hypolimnetic oxygenation increased oxygen concentrations throughout the hypolimnion, including down to the SWI, and induced mixing, although not to the extent observed during destratification. Subsequently, elevated Mn concentrations were observed to be restricted to the benthic waters located immediately over the sediments, while bulk (hypolimnion) water Mn concentrations remained low.
The good agreement between the model and the experimental data show that the model can be used as a predictive tool when designing and operating bubble-plume diffusers. Linear bubble-plume diffusers provide sufficient horizontal and vertical spreading to enable oxygen to reach the sediments. Hypolimnetic oxygenation, despite the increased HOD, is a viable method to manage the negative consequences of hypolimnetic anoxia in water-supply reservoirs. / Ph. D.
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Two-Dimensional Lake and Reservoir Modeling: Natural and Plume-Induced Mixing MechanismsMcGinnis, Daniel Frank 31 October 2003 (has links)
Lakes and reservoirs exhibit a number of mixing and transport mechanisms. Understanding the transport is crucial to understanding and predicting constituent and density structures. Transport in waterbodies can be natural, such as seiche-induced boundary mixing or advectively-driven inflows. Hypolimnetic oxygenation using bubble-plumes also leads to enhanced mixing. Whether natural or plume-induced, increased mixing will alter the waterbody properties. Conversely, the density structure affects the behavior of plumes as well as inflowing and outflowing water. For example, stratification resulting from impounding a river can result in nutrient and suspended solids retention. Similarly, operation of plumes can induce mixing in the hypolimnion, resulting in warming, increased nutrient transport, and resuspension of settled particles.
Modeling is extremely useful in determining the effects of dams on water quality constituents, enhanced transport, and the performance of mitigation techniques, such as hypolimnetic oxygenation. In this work, a variety of modeling techniques are used to evaluate natural and man-made mixing mechanisms. These include simple temperature and mass budgets, a two-dimensional lake model, and a two-phase plume model.
A bubble-plume and plume-enhanced mixing was studied in Lake Hallwil. It was found that the plume-lake interaction was much more complex then previously expected, and knowledge of the seiche- and plume-enhanced near-field was necessary to accurately model the plume performance. A two-dimensional lake model was then coupled with a linear-plume model to accurately predict not only the plume performance, but also the plume-enhanced mixing in Spring Hollow Reservoir. The same two-dimensional lake model, used in conjunction with data analysis, demonstrated that the Iron Gate I Reservoir was not a significant sink for suspended solids, with only the large, adjacent side bay (Orsova Bay) thought to be the permanent sink. Furthermore, significant stratification did not develop, preventing substantial primary productivity. While the impoundment did change the water quality characteristics, the extent is much less than previously expected. The modeling methods presented here and the coupled plume-reservoir model should be useful tools for the design, modeling and greater understanding of bubble-plumes and other transport-related phenomena in lakes and reservoirs. / Ph. D.
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A computer model for circular and linear bubble plumesRoyston, Wendy Cox 18 September 2008 (has links)
The purposes of this research were to implement the circular plume model developed by Wuest et al. (1992) and to develop and verify a linear plume model based on the circular model. The linear model developed is the first that models a bubble plume generated by a linear source in thermally stratified water and considers the effects of gas transfer between the bubbles and surrounding water.
The basis for both models is eight differential flux equations which are solved numerically using Euler’s method. Knowledge of ambient temperature, dissolved solids, dissolved oxygen, and dissolved nitrogen profiles as well as gas input rate, diffuser dimensions, and initial bubble size are required to implement the models.
The implementation of the circular model was successful as the results obtained corresponded with those reported by Wuest et al. (1992). The linear model made predictions very similar to those made by the circular model and, therefore, was also considered to perform well. Comparisons of the linear model with available data met with limited success. Initially, the linear model’s predictions of laboratory scale plume velocity data resulted in overpredictions of 40 to 50 percent when compared to actual data. Error in predictions of laboratory scale oxygen transfer data were greater than 100 percent. The model fared better when its predictions were compared to full scale data; the predicted temperature was within 7 percent of that measured at three depths and the predicted oxygen concentration was within 4, 20, and 38 percent for the three depths. Some of the discrepancies in the data likely result from the fact that the Froude number used in the model to calculate initial velocity was derived for a circular, rather than a linear, source. Determination of the appropriate linear Froude number would likely improve the model’s predictions. / Master of Science
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Entrainment and mixing properties of multiphase plumes: Experimental studies on turbulence and scalar structure of a bubble plumeSeol, Dong Guan 15 May 2009 (has links)
This dissertation presents a series of laboratory experiments to study flow and mixing
properties of multiphase plumes. The particle image velocimetry (PIV) and laserinduced
fluorescence (LIF) techniques are developed to measure two-dimensional velocity
and concentration fields of multiphase plumes. The developed measurement
techniques are applied to bubble plumes in different ambient conditions.
The problems and errors in the two-phase PIV application to a bubble plume case
are addressed through a comparative study between the optical separation method
using fluorescent particles and a new phase separation method using vector postprocessing.
The study shows that the new algorithm predicts well the instantaneous
and time-averaged velocity profiles and has errors comparable to those for image
masking techniques.
The phase separation method developed in the previous section is applied to
study the mean flow characteristics of a bubble plume in quiescent and unstratified
condition. The entrainment coefficients representing the mixing properties of a bubble
plume are calculated to lie between 0.08 near the plume source and 0.05 in the upper
region, and to depend on the non-dimensional quantity us/(B/z)1/3, where us is the
bubble slip velocity, B is the initial buoyancy flux, and z is the height from the diffuser.
Further, the LIF technique is investigated to measure the scalar concentration
field around a bubble plume in quiescent, unstratified condition. This new application
to bubble plumes accounts for light scattering by bubbles using an attenuation coef-
ficient that is proportional to the local void fraction. Measured scalar concentration
fields show similar trend in concentration fluctuation to turbulent plume cases.
Finally, the velocity and concentration field measurements using the developed
two-phase PIV and LIF methods are applied for a bubble plume in a density-stratified
ambient. The turbulent flow characteristics induced by a bubble plume in a stratified
ambient water are studied. The plume fluctuation frequency is measured as about 0.1
Hz and compares well to plume wandering frequency measured in unstratified plume
cases.
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Hypolimnetic Oxygenation: Coupling Bubble-Plume and Reservoir ModelsSingleton, Vickie L. 29 April 2008 (has links)
When properly designed, hypolimnetic aeration and oxygenation systems can replenish dissolved oxygen in water bodies while preserving stratification. A comprehensive literature review of design methods for the three primary devices was completed. Using fundamental principles, a discrete-bubble model was first developed to predict plume dynamics and gas transfer for a circular bubble-plume diffuser. This approach has subsequently been validated in a large vertical tank and applied successfully at full-scale to an airlift aerator as well as to both circular and linear bubble-plume diffusers. The unified suite of models, all based on simple discrete-bubble dynamics, represents the current state-of-the-art for designing systems to add oxygen to stratified lakes and reservoirs.
An existing linear bubble plume model was improved, and data collected from a full-scale diffuser installed in Spring Hollow Reservoir, Virginia (U.S.A.) were used to validate the model. The depth of maximum plume rise was simulated well for two of the three diffuser tests. Temperature predictions deviated from measured profiles near the maximum plume rise height, but predicted dissolved oxygen profiles compared very well to observations. Oxygen transfer within the hypolimnion was independent of all parameters except initial bubble radius. The results of this work suggest that plume dynamics and oxygen transfer can successfully be predicted for linear bubble plumes using the discrete-bubble approach.
To model the complex interaction between a bubble plume used for hypolimnetic oxygenation and the ambient water body, a model for a linear bubble plume was coupled to two reservoir models, CE-QUAL-W2 (W2) and Si3D. In simulations with a rectangular basin, predicted oxygen addition was directly proportional to the update frequency of the plume model. W2 calculated less oxygen input to the basin than Si3D and significantly less mixing within the hypolimnion. The coupled models were then applied to a simplified test of a full-scale linear diffuser. Both the W2 and Si3D coupled models predicted bulk hypolimnetic DO concentrations well. Warming within the hypolimnion was overestimated by both models, but more so by W2. The lower vertical resolution of the reservoir grid in W2 caused the plume rise height to be over-predicted, enhancing erosion of the thermocline. / Ph. D.
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Predicting induced sediment oxygen flux in oxygenated lakes and reservoirsBierlein, Kevin Andrew 02 June 2015 (has links)
Bubble plume oxygenation systems are commonly used to mitigate anoxia and its deleterious effects on water quality in thermally stratified lakes and reservoirs. Following installation, increases in sediment oxygen flux (JO2) are typically observed during oxygenation and are positively correlated with the bubble plume gas flow rate. Studies show that JO2 is controlled by the thickness of the diffusive boundary layer (DBL) at the sediment-water interface (SWI), which is in turn controlled by turbulence. As a result, JO2 can be quite spatially and temporally variable.
Accurately predicting oxygenation-induced JO2 is vitally important for ensuring successful oxygenation system design and operation. Yet despite the current understanding of physical and chemical controls on JO2, methods for predicting oxygenation-induced JO2 are still based on empirical correlations and factors of safety. As hypolimnetic oxygenation becomes more widely used as a lake management tool for improving and maintaining water quality, there is a need to move from the current empirically based approach to a mechanistic approach and improve the ability to predict induced JO2. This work details field campaigns to investigate and identify appropriate models of oxygen supply to the SWI and oxygen demand exerted from the sediment, with the intent to use these models to predict oxygenation-induced JO2.
Oxygen microprofiles across the SWI and near-sediment velocity measurements were collected in situ during three field campaigns on two oxygenated lakes, providing simultaneous measurements of JO2 and turbulence. Field observations show that oxygenation can increase JO2 by increasing bulk hypolimnetic oxygen concentrations, which increases the concentration gradient across the SWI. Oxygenation can also enhance turbulence, which decreases the DBL thickness and increases JO2. Existing models of interfacial flux were compared to field measurements to determine which model best predicted the observed JO2. Models based on the Batchelor scale, friction velocity, and film-renewal theory all agree reasonably well with field observations in both lakes. Additionally, the oxygen microprofiles were used to fit a transient model of oxygen kinetics in lake sediment and determine the appropriate kinetic model. Oxygen microprofiles in both lakes can be described using zero-order kinetics, rather than first-order kinetics.
The interfacial flux and sediment kinetic models are incorporated into a coupled bubble plume and 3-D hydrodynamic lake model, allowing for spatial and temporal variation in simulated JO2. This comprehensive model was calibrated and validated to field data from two separate field campaigns on Carvin's Cove Reservoir, Virginia. Simulated temperature profiles agreed quite well with field observations, while simulated oxygen profiles differed from observed profiles, particularly in the bottom 1 m of the water column. The model overestimates oxygen concentrations near the sediment, which results in higher simulated JO2 than was observed during the field campaigns. These discrepancies are attributed to oxygen-consuming chemical processes, such as oxidation of soluble metals, which are not accounted for in the hydrodynamic model. Despite this, the model is still able to capture the impact of bubble plume operation on JO2, as simulated JO2 is higher when the diffusers are operating. With some additional improvements to the water quality modeling aspects of the model, as well as further calibration and validation, the model should be able to reproduce observed JO2 provided oxygen concentrations near the SWI are accurately reproduced as well. The current work is an attempt to push toward a comprehensive lake oxygenation model. A comprehensive model such as this should improve the ability to predict oxygenation-induced JO2 and lead to improvements in the design and operation of hypolimnetic oxygenation systems. / Ph. D.
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[en] EXPERIMENTAL EVALUATION OF GAS DISPERSION IN OSCILLATORY CROSS FLOW OF LIQUID / [pt] AVALIAÇÃO EXPERIMENTAL DA DISPERSÃO DE GÁS EM ESCOAMENTO CRUZADO OSCILATÓRIO DE LÍQUIDOPHILLYPE DE LIMA MASSARI 26 July 2017 (has links)
[pt] Este trabalho apresenta uma investigação experimental do escoamento induzido pela interação entre uma pluma de bolhas e um escoamento cruzado oscilatório. Condições de escoamento similares podem ser encontrados em processos de aeração artificial utilizados na mitigação da poluição nos rios e na representação de vazamento de gás natural no fundo dos oceanos. No presente trabalho, ondas superficiais controladas foram inseridas em um canal de água para gerar oscilações na corrente do escoamento cruzado. As ondas foram geradas a partir de uma placa móvel na superfície da água e determinadas condições de escoamento instável foram selecionadas para a investigação. O ar foi injetado pelo fundo do canal para formar a pluma de bolhas. A técnica Particle Image Velocimetry (PIV) foi empregada para medir a velocidade do escoamento. Antes da estimativa da velocidade, as imagens foram pré-processadas aplicando-se rotinas desenvolvidas no Matlab a fim de distinguir as partículas traçadoras das bolhas de ar e criar máscaras dinâmicas para as imagens do sistema PIV. Assim, o campo vetorial de velocidade foi estimado utilizando algoritmos padrão do PIV. Além disso, as propriedades das bolhas, como tamanho e velocidade, também foram estimadas a partir das imagens adquiridas. Finalmente, foi analisada a interação entre a pluma de bolhas com o escoamento cruzado instável. / [en] This work presents an experimental investigation of the flow field induced by the interaction between a bubble plume and an oscillating cross flow. Similar flow conditions can be found in artificial aeration processes used for mitigation of pollution contamination in rivers and submarine outfalls in coastal areas. The mixing zone is highly dependent of the flow field near the plume hence the efficiency of aeration processes. In the present work, controlled surface waves were introduced to generate oscillations in streamwise and wall normal components of the cross flow. The waves were excited with a moving paddle and unsteady flow conditions were selected for the investigation. Air was injected in the bottom wall of the water channel to form the bubble plume. Particle Image Velocimetry (PIV) techniques were employed to measure the velocity flow field. Prior to velocity estimation, images were pre-processed using Matlab routines in order to distinguish tracer particles from air bubbles and to create a dynamic mask for the PIV images. Thus, the velocity vector field was estimated using standard PIV algorithms. In addition, properties of the bubbles, such as size and velocity, were also estimated from the acquired images. Finally, the interaction between the bubble plume with the unsteady cross flow was analyzed.
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Liquid metal flows drive by gas bubbles in a static magnetic fieldZhang, Chaojie 02 February 2010 (has links) (PDF)
This thesis presents an experimental study which investigates the behaviour of gas bubbles rising in a liquid metal and the related bubble-driven flow under the influence of external DC magnetic fields. The experimental configuration considered here concerns a cylindrical container filled with the eutectic alloy GaInSn. Argon gas bubbles are injected through a single orifice located at the container bottom in the centre of the circular cross-section. A homogeneous magnetic field was generated by a Helmholtz configuration of a pair of water-cooled copper coils. The magnetic field has been imposed either in vertical direction parallel to the main bubble motion or in horizontal direction, respectively. A vertical magnetic field stabilizes and damps the liquid metal flow effectively. The temporal variations of the fluid velocity with time become smaller with increasing magnetic induction. The velocity magnitudes are decreased, and the velocity distributions along the magnetic field lines are smoothed. The flow field keeps the axisymmetric distribution. A horizontal magnetic field destabilizes and enhances the flow within a range of moderate Hartmann numbers (100 < Ha < 400). The flow becomes non-axisymmetric due to the non-isotropic influence of the magnetic field. In the meridional plane parallel to the field lines, the flow changes its direction from a downward to an upward motion. Enhanced downward flows were observed in the meridional plane perpendicular to the field lines. The liquid velocity in both planes shows strong, periodic oscillations. The fluid motion is dominated by large-scale structures elongated along the magnetic field lines over the entire chord lengths of the circular cross-section.
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Liquid metal flows drive by gas bubbles in a static magnetic fieldZhang, Chaojie 18 January 2010 (has links)
This thesis presents an experimental study which investigates the behaviour of gas bubbles rising in a liquid metal and the related bubble-driven flow under the influence of external DC magnetic fields. The experimental configuration considered here concerns a cylindrical container filled with the eutectic alloy GaInSn. Argon gas bubbles are injected through a single orifice located at the container bottom in the centre of the circular cross-section. A homogeneous magnetic field was generated by a Helmholtz configuration of a pair of water-cooled copper coils. The magnetic field has been imposed either in vertical direction parallel to the main bubble motion or in horizontal direction, respectively. A vertical magnetic field stabilizes and damps the liquid metal flow effectively. The temporal variations of the fluid velocity with time become smaller with increasing magnetic induction. The velocity magnitudes are decreased, and the velocity distributions along the magnetic field lines are smoothed. The flow field keeps the axisymmetric distribution. A horizontal magnetic field destabilizes and enhances the flow within a range of moderate Hartmann numbers (100 < Ha < 400). The flow becomes non-axisymmetric due to the non-isotropic influence of the magnetic field. In the meridional plane parallel to the field lines, the flow changes its direction from a downward to an upward motion. Enhanced downward flows were observed in the meridional plane perpendicular to the field lines. The liquid velocity in both planes shows strong, periodic oscillations. The fluid motion is dominated by large-scale structures elongated along the magnetic field lines over the entire chord lengths of the circular cross-section.
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Experimental Investigations on Impinging Liquid Jets with Gas EntrainmentMelzer, Dana 27 November 2018 (has links)
The phenomenon of gas entrainment, as a result of impinging liquid jets, was experimentally investigated. The purpose of these investigations was to create a solid experimental database necessary for the development and validation of computational fluid dynamics (CFD) codes. In this work, various experimental setups were built to allow employing various imaging measurement techniques with high spatial and temporal resolution.
High-speed imaging was applied for characterizing the flow structure that develops under the free surface. It was found that gas entrainment takes place as soon as the jet impact velocity overcomes the value of 1.2 m/s. The bubble plume, formed as a result of impingement, consists of two distinct regions: an inner region with high turbulence and fine freely
dispersed bubbles and an outer region, where larger bubbles move towards the free surface. Two mechanisms are responsible for the occurrence of gas entrainment. High-speed camera observations were validated by means of ultrafast x-ray computed tomography, an innovative non-intrusive measurement technique. Also, quantitative information regarding
the bubble plume was acquired from the high-speed observations, in terms of: penetration depth, width and spreading angle of the bubble plume.
Measurements, based on two wire-mesh sensors, were performed to assess the gas entrainment rate. In these measurements, void fraction distributions and gas velocities were quantified. The entrainment rate was calculated as an integral over the entrained volumetric gas fraction. It was found to be a function of the jet velocity and length. Results were validated using dual-plane x-ray computed tomography. Results were in agreement with the ones obtained from the wire-mesh sensors and approximately four to six times smaller than predictions found in related publications.
Instantaneous as well as time-averaged velocity fields of the continuous phase were gained by means of particle image velocimetry (PIV). Axial time-averaged velocities followed a power law profile, typical for fully developed flow conditions. Two recirculating vortices were found in the flow: one occurs as a result of the water adhering to the lateral wall of
the tank and the flow being confined by the bottom wall, while the second one is generated in the wake of rising bubbles. Bubble entrainment was found to reduce liquid phase mean velocities and to enhance fluctuations in the streamwise direction. This is reflected in the distribution of the turbulence kinetic energy.
Last but not least, several examples of comparisons between experimental data and CFD results stand to demonstrate the importance of the experimental observations gathered in the frame of this work. It is shown that the experimental data provides a good basis not only for qualitative comparisons, but also for quantitative correlations.
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