Assessment of FLUENT CFD code as an analysis tool for SCW applications

Farah, Amjad

01 August 2012

Chosen as one of six Generation‒IV nuclear-reactor concepts, SuperCritical Water-cooled Reactors (SCWRs) are expected to have high thermal efficiencies within the range of 45 ‒ 50% owing to the reactor‟s high pressures and outlet temperatures. The behaviour of supercritical water however, is not well understood and most of the methods available to predict the effects of the heat transfer phenomena within the pseudocritical region are based on empirical one-directional correlations which do not capture the multi-dimensional effects and do not provide accurate results in regions such as the deteriorated heat transfer regime. Computational Fluid Dynamics (CFD) is a numerical approach to model fluids in multidimensional space using the Navier-Stokes equations and databases of fluid properties to arrive at a full simulation of a fluid dynamics and heat transfer system. In this work, the CFD code, FLUENT-12, is used with associated software such as Gambit and NIST REFPROP to predict the Heat Transfer Coefficients at the wall and corresponding wall temperature profiles inside vertical bare tubes with SuperCritical Water (SCW) as the cooling medium. The numerical results are compared with experimental data and 1-D models represented by existing empirical correlations. Analysis of the individual heat-transfer regimes is conducted using an axisymmetric 2-D model of tubes of various lengths and composed of different nodes count along the heated length. Wall temperatures and heat transfer coefficients were analyzed to select the best model for each region (below, at and above the pseudocritical region). To neutralize effects of the rest of the tube on that region, smaller meshes were used were possible. Two turbulent models were used in the process: k-ε and k-ω, with many variations in the sub-model parameters such as viscous heating, thermal effects, and low-Reynolds number correction. Results of the analysis show a fit of ±10% for the wall temperatures using the SST k-ω model in the deteriorated heat transfer regime and less than ±5% for the normal heat transfer regime. The accuracy of the model is higher than any empirical correlation tested in the mentioned regimes, and provides additional information about the multidimensional effects between the bulk-fluid and wall temperatures. Despite the improved prediction capability, the numerical solutions indicate that further work is necessary. Each region has a different numerical model and the CFD code cannot cover the entire range in one comprehensive model. Additionally, some of the trends and transitions predicted are difficult to accept as representation of the true physics of SCW flow conditions. While CFD can be used to develop preliminary design solutions for SCW type reactors, a significant effort in experimental work to measure the actual phenomena is important to make further advancements in CFD based analysis of SCW fluid behaviour. / UOIT

CFD

FLUENT

SCW

Heat transfer

Bare tube

The Characterization and Feasibility of a Low-Duty-Cycle Diaphragmless Shock Tube

Taylor, David Christopher

2012 August 1900

The feasibility and characterization of a novel diaphragmless shock tube was examined at the National Aerothermochemistry Laboratory at Texas A&M University. The goal was to design a facility that reliably produces shock waves through air in a repeatable manner sufficient for statistical analysis. The device is modular, automated, and compact. The proposed diaphragmless shock tube uses a shock wave generating mechanism that consists of a rotating door and locking cam-shaft system. The facility produced the desired driver gas pressures repeatedly to within 0.31% at low-duty-cycle of 6 seconds. The driven gas pressure profiles within the test-section suggest that shock waves may be forming within test section for a driver gas pressure of 200 psig and above, which corresponds to shock wave Mach numbers of 1.7 to 2.0. The measured wave speeds were within 3.1% of that predicted by ideal shock tube theory; however, the induced driven gas pressures within the constant pressure region were approximately half that expedited from ideal shock tube theory.

Facility Development

Shock Tube

Aerospace Engineering

Influence of boundary conditions on the hydraulic-mechanical behaviour of an unsaturated swelling soil

Siemens, Gregory Allen

12 July 2006

The hydraulic-mechanical behaviour of swelling clay is examined in this thesis. The study includes laboratory testing and numerical modeling which considers the influence of boundary conditions on the hydraulic-mechanical behaviour of a compacted unsaturated swelling clay soil. The laboratory testing component of this research consists of three (3) series of tests using a newly modified triaxial apparatus on which mechanical and hydraulic boundary conditions are altered during liquid infiltration. Mechanical boundary conditions range from constant volume to constant mean stress and also include constant stiffness which is a spring type boundary consisting of both volume expansion and mean stress increase. Hydraulic boundary conditions include drained and undrained flow into triaxial specimens. The numerical modeling component of this research includes the creation of a new capillary tube model for swelling clay materials and incorporates dynamic changes to the cross-sectional area for flow. Laboratory results are modeled using the capillary tube model, an empirical hydraulic model, D’Arcy’s Law, and in an elastic-plastic context for unsaturated soil. Results of the laboratory and numerical modeling components show that boundary conditions dominate the hydraulic-mechanical behaviour of unsaturated swelling clay soil during liquid infiltration. In particular, a mechanism is shown to explain how hydraulic conductivity of a swelling soil can decrease with increasing water content at constant void ratio. Finally hydraulic and mechanical behaviour cannot be considered separately in swelling materials due to the intimate relationship in their response. / October 2006

unsaturated

swelling soil

suction

laboratory

capillary tube

Neural Tube Defect-causing Teratogens Affect Tissue Mechanical Properties and Cytoskeletal Morphology in Axolotl Embryos

Kakal, Fatima

January 2007

The teratogenic drugs cytochalasin B and valproic acid have been shown to alter F-actin polymerization, an effect that is crucial in forming microfilaments. Microfilaments form important cytoskeletal structures that maintain the structural integrity of the cell, cause cell motility and cell migration. Microfilament alterations are known to cause neural tube defects such as spina bifida and anencephaly (Walmod et al., 1999). We here aim to show that disruption of microfilaments by cytochalasin B and valproic acid affects the tensile properties of the tissue. Biomechanics is an interdisciplinary field that allows mechanical concepts to help us understand embryo development. This project used a novel tissue stretching device that measures the tensile properties of neural and epidermal tissue. The instrument used a pair of cantilevered wires to which the specimen was glued. This device stretched the mid-neural and -lateral tissue anterior-posterior (AP) and medio-lateral (ML) unidirectionally. The tensile properties of the tissue were determined by Resultant Young’s Modulus that depends on the true stress and true strain in the tissue sample. The experiment was conducted at a strain rate of 50%. Axolotl embryos were treated with 5ug/mL and 2.5ug/mL cytochalasin B and 5mM valproic acid at stage 13 (early neurula) for an hour, washed, and allowed to develop to stage 15 before it was used in the uniaxial tissue stretcher. Changes in the F-actin filaments were analysed by phalloidin staining and viewed under a confocal microscope. The tests show that disruption of microfilaments by cytochalasin B increases the stiffness of the dorsal-tissue by as much as 101% for CB-treated tissues stretched in the AP direction and 298% when stretched in the ML direction. VA-treated neural plate tissue showed a stiffness increase of 278% when stretched in the AP direction and 319%, when stretched in the ML direction. Changes in the F-actin filaments are quantified by phalloidin staining viewed with confocal microscopy. These findings indicate that direction-dependent mechanical forces in the tissue are contributing factors in closure of the neural tube in axolotl embryos.

Teratogens

Cytoskeleton

Axolotls

Neural-tube

Biology

Neural Tube Defect-causing Teratogens Affect Tissue Mechanical Properties and Cytoskeletal Morphology in Axolotl Embryos

Kakal, Fatima

January 2007

The teratogenic drugs cytochalasin B and valproic acid have been shown to alter F-actin polymerization, an effect that is crucial in forming microfilaments. Microfilaments form important cytoskeletal structures that maintain the structural integrity of the cell, cause cell motility and cell migration. Microfilament alterations are known to cause neural tube defects such as spina bifida and anencephaly (Walmod et al., 1999). We here aim to show that disruption of microfilaments by cytochalasin B and valproic acid affects the tensile properties of the tissue. Biomechanics is an interdisciplinary field that allows mechanical concepts to help us understand embryo development. This project used a novel tissue stretching device that measures the tensile properties of neural and epidermal tissue. The instrument used a pair of cantilevered wires to which the specimen was glued. This device stretched the mid-neural and -lateral tissue anterior-posterior (AP) and medio-lateral (ML) unidirectionally. The tensile properties of the tissue were determined by Resultant Young’s Modulus that depends on the true stress and true strain in the tissue sample. The experiment was conducted at a strain rate of 50%. Axolotl embryos were treated with 5ug/mL and 2.5ug/mL cytochalasin B and 5mM valproic acid at stage 13 (early neurula) for an hour, washed, and allowed to develop to stage 15 before it was used in the uniaxial tissue stretcher. Changes in the F-actin filaments were analysed by phalloidin staining and viewed under a confocal microscope. The tests show that disruption of microfilaments by cytochalasin B increases the stiffness of the dorsal-tissue by as much as 101% for CB-treated tissues stretched in the AP direction and 298% when stretched in the ML direction. VA-treated neural plate tissue showed a stiffness increase of 278% when stretched in the AP direction and 319%, when stretched in the ML direction. Changes in the F-actin filaments are quantified by phalloidin staining viewed with confocal microscopy. These findings indicate that direction-dependent mechanical forces in the tissue are contributing factors in closure of the neural tube in axolotl embryos.

Teratogens

Cytoskeleton

Axolotls

Neural-tube

Biology

OH* Chemiluminescence: Pressure Dependence of O + H + M = OH* + M

Donato, Nicole

2009 December 1900

The measure of chemiluminescence from the transition of the hydroxyl radical from its electronically excited state (A^2 Sigma^positive) to its ground state (X^2 Pi) is used in many combustion applications for diagnostic purposes due to the non-intrusive nature of the chemiluminescence measurement. The presence of the ultraviolet emission at 307nm is often used as an indicator of the flame zone in practical combustion systems, and its intensity may be correlated to the temperature distribution or other parameters of interest. To date, the measurement of the excited state OH, OH*, is mostly qualitative. With the use of an accurate chemical kinetics model, however, it is possible to obtain quantitative measurements. Shock-tube experiments have been performed in highly diluted mixtures of H2/O2/Ar at a wide range of pressures to evaluate the pressure-dependent rate coefficient of the title reaction. In such mixtures the main contributing reaction to the formation of OH* is, O H M = OH* M. R1 Previous work has determined the reaction rate of R1 at atmospheric conditions and accurately predicts the amount of OH* experimentally produced. At elevated pressures up to 15 atm, which are of interest to the gas turbine community, the currently used reaction rate of R1 (i.e., without any pressure dependence) significantly over predicts the amount of OH* formed. This work provides the pressure dependence of R1. The new reaction rate is able to reproduce the experimental data over the range of conditions studied and enables quantitative measurements applicable to practical combustion environments.

Shock-Tube

Chemiluminescence

Chemical Kinetics

OH*

Chemiluminescence and Ignition Delay Time Measurements of C9H20 Oxidation in O2-Ar Behind Reflected Shock Waves

Rotavera, Brandon

2009 December 1900

Stemming from a continuing demand for fuel surrogates, composed of only a few species, combustion of high-molecular-weight hydrocarbons (>C5) is of scientific interest due to their abundance in petroleum-based fuels, which contain hundreds of different hydrocarbon species, used for military, aviation, and transportation applications. Fuel surrogate development involves the use of a few hydrocarbon species to replicate the physical, chemical, combustion, and ignition properties of multi-component petroleum-based fuels, enabling fundamental studies to be performed in a more controlled manner. Of particular interest are straight-chained, saturated hydrocarbons (n-alkanes) due to the high concentration of these species in diesel and jet fuels. Prior to integrating a particular hydrocarbon into a surrogate fuel formulation, its individual properties are to be precisely known. n-Nonane (n-C9H20) is found in diesel and aviation fuels, and its combustion properties have received only minimal consideration. The present work involves first measurements of n-C9H20 oxidation in oxygen (O2) and argon (Ar), which were performed under dilute conditions at three levels of equivalence ratio (phi = 0.5, 1.0, and 2.0) and fixed pressure near 1.5 atm using a shock tube. Utilizing shock waves, high-temperature, fixed-pressure conditions are created within which the fuel reacts, where temperature and pressure are calculated using 1D shock theory and measurement of shock velocity. Of interest were measurements of ignition times and species time-histories of the hydroxyl (OH*) radical intermediate. A salient pre-ignition feature was observed in fuel-lean, stoichiometric, and fuel-rich OH* species profiles. The feature at each equivalence ratio was observed above 1400 K with the time-of-initiation (post reflected-shock) showing dependence on phi as the initiation time shortened with increasing phi. Relative percentage calculations reveal that the fuel-rich condition produces the largest quantity of pre-ignition OH*. Ignition delay time measurements and corresponding activation energy calculations show that the phi = 1.0 mixture was the most reactive, while the phi = 0.5 condition was least reactive.

Nonane

oxidation

chemiluminescence

shock tube

ignition

Survey for Intergeneric Pollen Tube Growth in Intergeneric Pollinations Utilizing the iap Allele in Sorghum bicolor

Bartek, Matthew Scott

2010 December 1900

Hybridization within Sorghum bicolor (L.) Moench has been the primary means of creating genetic diversity needed for sorghum crop improvement. While significant variation exists within S. bicolor, there are several traits that can be improved and potential opportunities to improve S. bicolor if secondary and tertiary germplasm pools could be accessed. Recently, the discovery of the iap (Inhibition of Alien Pollen) mutant and its introgression into more breeding-amenable genetic background has facilitated the development of S. bicolor germplasm with genetic diversity not previously seen within Sorghum. The key to producing this variation is the homozygous recessive mutant gene iap which removes an important reproductive isolation barrier to hybridization. Development of a S. bicolor accession (Tx3361) containing the mutant allele iap and ms3 has allowed introgression of genomic regions from divergent sorghum species into S. bicolor. Given the success with divergent sorghum species, there is a real interest in assessing the potential of this mutant to facilitate intergeneric hybridization. The objective of this study was to determine the range and effectiveness of the iap mutant to allow pollen tubes of Poaceae species outside of the genus Sorghum to grow into S. bicolor pistils. Accessions from the genera Zea, Miscanthus, Pennisetum, and Sorghastrum were used as pollen donors onto Tx3361 and fluorescent microscopy was used to determine the distance through the pistils that foreign pollen tubes grew. Results indicate high levels of pollen tube growth into the ovaries of S. bicolor pistils for two accessions of Pennisetum ciliare (L.) Link and four accessions of Zea mays L. Pollen tubes of other accessions tested did grow to the ovary but in very small numbers. While the recovery of embryos was not attempted in this study, the results indicate that there is potential for hybridization, but the specific pollinator within a species is critical in this attempt.

Sorghum

iap

intergeneric crosses

pollen tube

Study on measurements of friction coefficient in tube hydroforming

Huang, Li-Shang

05 August 2004

ABSTRACT The objective of this study is to obtain the friction coefficient of lubricants in tube hydroforming of guiding zone. Lubricants, universal testing machine, and friction test machine in tube hydroforming of guiding zone are used to carry out the experiments of aluminum alloy tubes. Lubricants are categorized according to their performance as follows: (1) oils, (2) emulsions, and (3) slide lacquer. Different lubricants tests, it is known that the best lubrication is derived from slide lacquer, while oils showed the poorest behavior. Different internal pressure tests, it is known that greater internal pressure causes the coefficient of friction decreasing. Different sliding velocity, it is known that sliding velocity does not affect the coefficient of friction at 100mm/min. And using CCD which is an optical instrument obtains the surface of tubes after experiments.

Lubricant

Friction coefficient test

Tube hydro forming

Manufacturing of three-way pipe fitting hydroforming machine

Lin, Zih-Cyuan

06 September 2005

The objective of this study is design and manufacture a tube hydroforming machine with counter feeding and axial feeding, which includes a forming apparatus, hydraulic system and control system. Using computer program to execute the loading path and correct by sensors. To test the function of the machine, carry out the experiments of T,Y-shape hydraulic bulging with annealed AA6063-T5 and 6011A aluminum, which by different working path, and using the experiments to analyze the influences of these parameters on the formability of the tubes.

loading path

tube hydroforming

counter force