Initial Fill Research Articles

Analysis of thermodynamic processes involving hydrogen

There is a need to explore potential hazard scenarios associated with several specific thermodynamic processes involving the storage and use of hydrogen subjected to thermal exposures. A potential real-life scenario is the heating of a hydrogen storage vessel abroad a hydrogen-powered vehicle in an automobile fire or in an accident at a refueling station. The effect of thermal exposures on these thermodynamic processes has been examined using the National Institute of Standards and Technology (NIST) REFPROP, Reference Fluid Thermodynamic and Transport Properties, database. The thermodynamic processes considered are isochoric (constant density) heating, isenthalpic expansion, and isentropic expansion. In addition, isochoric heating followed by either an isenthalpic or isentropic expansion process is also discussed. The initial fill density of a hydrogen system has a significant effect on the subsequent thermodynamic processes. From a standpoint of fire safety, a hydrogen system subjected to thermal exposure or preheating before an isenthalpic expansion would potentially increase the risk of fire, especially when the exposure temperature is very close to the hydrogen autoignition temperature.

The physics of a stove-top espresso machine

The operation of a common type of stove-top espresso machine is analyzed to determine the initial fill conditions required to have the coffee extracted in the optimum temperature range of 90°C–95°C. By using the gas laws and some benchtop experiments, it is shown that the pressure in the vessel increases much more slowly than does the saturated vapor pressure of water at the temperature of the vessel. For any given final temperature, the volume of coffee that can be extracted is linearly proportional to the initial volume of air in the pressure vessel; that is, the higher the fill level, the smaller the volume of coffee that can be extracted. It is also shown that for typical operating conditions for which the water is initially at room temperature, half of the coffee is extracted when the water temperature is below 70°C, which is much less than the desirable temperature, and that hotter coffee extraction temperatures will result if the water is preheated to about 70°C before the pressure vessel is sealed and at least 100ml of air space is left in the vessel. Experiments confirming the analysis use easily obtained equipment and are appropriate for undergraduate laboratory work, with the added attraction that students can enjoy consuming the results of the experiments.

Analysis of a rapid supercritical extraction aerogel fabrication process: Prediction of thermodynamic conditions during processing

Aerogels have unusual mechanical and thermal properties that render them useful in a range of applications from thermal insulators to chemical sensors. However, aerogel fabrication can be difficult, typically requiring the use of supercritical extraction of solvent from the sol–gel matrix. We employ a rapid supercritical extraction (RSCE) technique for aerogel fabrication that is faster and simpler than the standard methods. This technique relies on a hydraulic hot press to heat the chemical precursors and provide the required temperature and pressure increase needed to reach a supercritical state within a contained mold. Experimental results show that the pressure–temperature curve is characterized by a ‘take-off point’ and a ‘leak point’. The take-off point occurs at the start of a rapid increase in pressure and the leak point occurs where the pressure increase subsides. This paper presents an analytical model that predicts the pressure–temperature relationship of the aerogel precursors during the RSCE fabrication process and shows that the model can be extended to other RSCE systems. Using pure methanol, water and aerogel precursors in separate tests, the effects of initial liquid volume and press force on the pressure and temperature during processing were studied. We find that the take-off point can be estimated using a maximum specific volume model, which is a function of the initial percent volume fill of liquid used in the test. We are also able to predict the rapid pressure increase region observed during the process using a constant volume model. Leaking is determined to be a function of the mechanical forces acting on the system and occurs when the pressure in the contained mold nears the value of the pressure imparted onto the gasket by the hot press. The leak point pressure is found to be independent of the initial percent volume of liquid used in the test; however the leak point temperature decreases with increasing initial percent volume fill.

Contribution of Dental Amalgam to Urinary Mercury Excretion in Children: Woods et al. Respond

We are pleased to respond to Iavicoli and Carelli’s comments on our article (Woods et al. 2007). Iavicoli and Carelli question our use of creatinine adjustment; in previous studies, we addressed the pros and cons of this issue in depth (Heyer et al. 2007; Martin et al. 1996; Woods et al. 1998). In terms of the present study (Woods et al. 2007), instead of advocating one approach over the other, we presented data, where appropriate (e.g., Figure 2), as both adjusted and unadjusted measures to provide the reader access to both sets of results. Iavicoli and Carelli note only a slight difference in Figure 2 between comparisons of adjusted and unadjusted urinary Hg levels at year 7; in our article we explained the higher variability (not bias) in the unadjusted values. Because creatinine adjustment did not otherwise alter the urinary Hg findings in the study, as stated in our Figure 3 (Woods et al. 2007), we did not present adjusted values for data described in Figures 3 or 4. Iavicoli and Carelli’s comments about blood Hg levels are not relevant because we did not measure blood Hg concentrations in this study. Regarding Iavicoli and Carelli’s comment on “steady state,” data presented in our Figure 4 (Woods et al. 2007) allow the reader to discern the influence of additional amalgam treatment on Hg body burden over time, as inferred from annual urinary Hg levels. A comprehensive pharmacokinetic evaluation of Hg body burden was neither intended nor within the scope of this study. Iavicoli and Carelli speculate that Hg sulfide on teeth surfaces might have affected observed changes in urinary Hg levels; however, others (Brune 1986; Brune and Evje 1985; Gebel and Dunkelberg 1996) have clearly shown that sulfide (and other oxidation) layers are continuously removed by the effects of mastication, as well as by hot foods and liquids. These layers do regenerate but are in a constant state of flux. Because all of the amalgam used in this study (Woods et al. 2007) was of a single formulation, there would have been no variation in the tendency to form sulfide layers from amalgam treatment. Additionally, although there may have been some variation in oral pH among study subjects that could have influenced this process, Hg elimination still occurs at a relatively constant state. Therefore, we do not consider Hg sulfide film formation to be a significant factor in urinary Hg excretion over time. Iavicoli and Carelli question our use of “dose effect” to describe the relationship of amount of amalgam treatment received with urinary Hg concentration. However, we consider this depiction appropriate. Finally, Iavicoli and Carelli point out that the trend that children who received up to nine initial amalgam fillings but no subsequent treatment returned to pretreatment values within 1 year is not clear. This statement should have been “within 1 additional year” (i.e., by year 3 of follow-up). Urinary Hg levels were highest approximately 2 years after initial amalgam treatment for those with no subsequent treatment; those with ≥ 10 fillings at initial treatment and no subsequent treatment took > 3 years (approximately 5 years) to return to pretreatment levels. For Figure 4 (Woods et al. 2007), we obtained confidence intervals, but they were not included because of the clutter they created in the figures. Thus, the statements refer to trends and not statistical significance.

Contribution of Dental Amalgam to Urinary Mercury Excretion in Children

Woods et al. (2007) studied a group of children (n = 507) who were exposed by inhalation to elemental mercury (Hg0) from dental amalgam fillings. In the study, 253 subjects were exposed, whereas the remaining 254 children, the control group, were exposed to composite resin. We consider the experimental design of their study to be adequate, but we do have questions about their methods of data handling and interpretation. For example, we do not understand why instead of always using creatinine-adjusted Hg levels, they used—in some instances—unadjusted Hg levels. In fact, there is continuous alternation and exchange between the two biological concepts (i.e., between the unadjusted and the adjusted concentrations). There are at least three well-grounded and well-known reasons that creatinine adjustment is essential: a) urinary creatinine accounts for variations in 24-hr excretion (Aito et al. 1983); b) urinary creatinine adjustment reportedly reflects Hg blood levels (Smith et al. 1970) and possibly Hg body burden; and c) in the light of established knowledge, Hg blood levels reflect recent exposure (Piotrowski et al. 1975). Accordingly, the lack of significance between the Hg levels (not adjusted for creatinine) of the amalgam and the control subgroups at year 7, the final year of the study by Woods et al. (2007), is probably a bias that is indicated by the disappearance of overlapping if creatinine adjustment had been performed, as suggested by Aitio et al. (1983) as long as 25 years ago. Also, because no adjusted data were reported for male and female levels, the impact of such an adjustment cannot be conjectured by the reader. Subsequently this prevents accurate evaluation of the Hg level trend over the years. It should be pointed out that the data of Woods et al. (2007) do not allow us to extrapolate whether or not the exposed subgroup is in the steady state, because this condition depends on the time lag between urine collection and the last amalgam treatment(s). This limitation prevents an accurate interpretation of the decrease in urinary Hg levels over years. Geller (1976) reported that Hg sulfide can coat Hg0, thereby slowing down the release of Hg vapor. Although no specific study has determined whether this is true for amalgams, we cannot exclude that Hg oxidation may yield Hg sulfide on the amalgam surface. Woods et al. (2007) speculated about the decrease in Hg urinary excretion over years, but they did not consider the possibility of sulfide formation. Moreover, they did not explain the decrease in Hg levels over time after year 2 but simply stated that “the rate of urinary [Hg] excretion exceeds the rate of [Hg] exposure from dental amalgam.” The formation of a thin film of Hg sulfide on amalgam surfaces could be an explanation, especially since the Hg body burden—and consequently Hg urinary levels—may be either in the steady state or at an increasing elimination rate because of the addition of new fillings. Furthermore, we feel that the use of the term “dose–effect relationship” by Woods et al. (2007) is questionable. Also, it is not clear if the term “dose” refers to the number of additional amalgam fillings over the years or to the difference between means. Also, “effect” has a completely different meaning in toxicology. In this case, another term should be used to more accurately indicate the difference in two urinary Hg levels. In our opinion, “differential dose minus follow-up years” would be more appropriate in the text than “dose effect.” Woods et al. (2007) stated that in children who received “up to 9 initial amalgam fillings, urinary Hg returned to pre-treatment value within one year,” but this statement is not clear because this trend applies only to children who received 0–4 amalgam fillings at baseline but not to the group that received 5–9 [Figure 4; Woods et al. (2007)]. Finally, Woods et al. (2007) omitted error bars from their Figure 4; SE or SD could have been easily calculated by the theory of error propagation and would probably have addressed the discussion more accurately, or at least would have tempered some conclusions, especially with regard to confirmation of the “whole-body biological half-time of Hg on the order of 60–70 days.” This half-time is correct but there is a large margin of uncertainty based on the experimental data. In conclusion, although Woods et al. (2007) used a well-structured experimental design, their conclusions are not accurate because of their handling of the experimental results and their use of basic toxicology terminology.

Implementing a Hospital Vendor‐Managed Inventory System

ABSTRACTBackgroundTraditional pharmacy imprest services require deployment of pharmacy technicians and substantial stock holding. These costly requirements could be reduced by a vendor‐managed inventory system.AimTo reduce the number of staff required to provide imprest services, reduce stock holding, improve customer service and maintain fill rates.MethodVendor‐managed inventory was implemented at a major teaching hospital in December 2005 with all imprest sites checked and restocked by vendor staff. An analysis of pharmacy stock holding was conducted over a 15 month period (9 months pre‐implementation and 5 months post‐implementation). Customer satisfaction surveys were performed in July 2006 and January 2007. Random audits were conducted from January to August 2006 to measure fill rates.Results3.5 full‐time equivalent imprest staff were redeployed to clinical pharmacy support duties and stock holding decreased by $352 000. The initial customer satisfaction survey in July 2006 demonstrated an average score of 5 (0 = very poor, 10 = excellent) and subsequently a number of improvements were implemented. A second customer satisfaction survey in January 2007, showed a significant increase in customer satisfaction. Initial fill rates were lower than the target of 97%, but increased to above 98% after 4 months.ConclusionA hospital vendor‐managed inventory system was successfully implemented and subsequently rolled out to two other hospitals in the network. All key objectives were met and an ongoing quality audit program is in place.

Lithofacies characterization and channel development in the outcrops of cretaceous sedimentary rocks, Dahomey basin, southwestern Nigeria.

Outcrop exposures of Cretaceous sedimentary rocks in Benin Basin southwestern Nigeria, allow the recognition of slope related sediments and slope valleys. Detailed outcrop logging permits the delineation of massive to cross bedded loose sand with lateral facies changes, normally graded sandstone, clay with injected sand, clayey silt with abundant clasts, channel complexes associated with different lithologies, loose sand, very fine to coarse grained sandstone and conglomerate with clasts of sandstone and siltstone. These lithofacies revealed history of erosion and deposition in various proportions. Four sets of channel development were delineated; the initial valley cut, complex reincision and fill, regional erosion and channel abandonment. These four categories of channel development are related to significant erosion and are possibly related to periods of lowstands. The outcrop exposures show that the first set of channel infill probably commenced with deposition of turbidites accompanied by marine transgression associated with contemporaneous slumping. This progress vertically to amalgamated (network of channels) channels filled with diverse lithologic units while the topmost channel is filled with channel lag and conglomerate. Channel infills are composed essentially of sediments derived from turbidites, slumps and debris flows. Two types of architectural elements recognized are single-story channel and multistory channel complex. The different stages of channel development can be considered in terms of low efficiency and high efficiency flows, which are related to slope equilibrium. Keywords: Outcrop, slope, channel development, channel architecture, process model, lowstandJournal of Mining and Geology Vol. 43 (2) 2007: pp. 131-146

Granular segregation in discharging cylindrical hoppers: A discrete element and experimental study

The segregation of granular materials due to differences in particle properties occurs during a variety of handling and transport processes, such as flow from a hopper. In the present work, the discrete element method (DEM) is used to investigate segregation of granular materials during discharge from a hopper. The effects of various particle properties and hopper geometries on the segregation of a spherical, bidisperse granular material during hopper discharge are studied. Particle contacts are modeled using a soft-particle model consisting of a hysteretic spring system and sliding friction. The effects of the particle diameter ratio, density ratio, fines mass fraction, hopper wall angle, hopper cross-sectional shape, and the initial fill conditions are investigated. These computational results are compared to those from a small experimental system with the same hopper dimensions and particle properties. The use of this small-scale system permits a novel, one-to-one comparison with the DEM model predictions for the purpose of model validation. The experiments utilize bidisperse glass spheres in a small, Plexiglas cylindrical hopper that is used in the ASTM International standard test for sifting segregation. Particles are discharged from either a ‘mass-flow’ or ‘funnel-flow’ hopper design and collected transiently in equal volumes until the hopper is empty. Analysis of the weight fractions of fine and coarse particles is conducted by sieving. A comparison of the computational and experimental results provides an indication of the model's success at predicting segregation during hopper discharge and the applicability of the DEM model to other granular flow systems.

Nuclear measurements of fuel-shell mix in inertial confinement fusion implosions at OMEGA

Direct drive spherical implosions on the OMEGA laser system [T. R. Boehly et al., Opt. Commun. 133, 495 (1997)] have shown that increased capsule convergence results in increased susceptibility to fuel-shell mix. Mix results from saturation of the Rayleigh-Taylor instability, leading to small-scale, turbulent eddies and atomic-level mixing of the high-density compressed shell with hot, low-density fuel from the core. To sensitively probe the extent of mix, nuclear yields were measured from implosions of capsules filled with pure He3. The plastic capsule shell contains a deuterated plastic (CD) layer either on the inner surface or offset from the inner surface by 1μm. Mixing of D from the shell with hot He3 in the core is necessary to produce 14.7MeV DHe3 protons in such capsules. DHe3-proton spectral measurements have been used to constrain the amount of mix at shock time, to demonstrate that some of the fuel mixes with the offset CD layer, and that capsules with a higher initial fill density or thicker shell are less susceptible to the effects of mix.

Effect of Nozzle Type and Swirl on Flow Pattern for Initial Filling Conditions in the Mould for Up-hill Teeming

With increasingly more stringent requirements on steel quality and productivity in uphill teeming production, it is vital to attain more desirable fluid flow conditions in the filling of the mould. In this investigation, physical and mathematical modelling was carried out to study the effects of nozzle type and utilization of a swirl generator in the inlet nozzle on the flow pattern in the ingot mould during the initial filling period. Specific focus was on the effects on the resultant hump and axial velocities. Three cases were considered: 1) a straight nozzle, 2) a divergent nozzle, and 3) a divergent nozzle combined with a swirl generator. It was found that usage of the divergent nozzle, compared to the straight nozzle, resulted in a smaller hump and lower axial velocities in the bath. For the combination of divergent nozzle and swirl generator, these findings were even more pronounced, with the hump practically eliminated, and the axial velocities, as well as the turbulence at the meniscus, significantly lower. The findings of the study suggest that a divergent nozzle combined with a swirling flow generated in the nozzle could be used in the up-hill teeming process in purpose to get calmer initial filling conditions.

Influence of the initial rectal distension on posterior margins in primary and postoperative radiotherapy for prostate cancer

Background and purpose The aim of the study was to define the effect of different rectum fillings in the planning CT study on the posterior clinical target volume (CTV) displacements (PD) in primary and postoperative radiotherapy (RT) for prostate cancer. Materials and methods Fifty patients underwent CT scans in supine position with a full bladder and an empty bladder before RT and at several points in time during the treatment. PD were determined depending on the initial rectum volume (RV), average cross-sectional rectal area (CSA), and the rectal diameter at the level of the bladder neck (RD). Results Posterior CTV motion was not found to be minimal with a particularly small initial rectum filling. Steeply increasing PD resulted for patients with RV > 120 cm 3, CSA > 12 cm 2, and RD > 4.5 cm. While below these critical values a posterior margin of 6 mm/9 mm allowed to cover 80%/90% of displacements, 18 mm/24 mm were needed for patients with larger rectum fillings. No correlation of increasing rectum distension with increasing PD was found at the apex level. PD could not be reduced by voiding the bladder. Conclusions Defining the posterior margin in prostate RT, the initial rectum distension and the superior–inferior CTV level has to be considered. Patients with large initial rectum fillings have preferentially the need for repeated planning CT scans or image-guided RT.

Using LIDAR to Monitor a Beach Nourishment Project at Wrightsville Beach, North Carolina, USA

Abstract With beach nourishment widely used today to combat shoreline erosion, it is desirable to monitor the postnourishment shoreline to evaluate the projects' success. Implementing a monitoring program is difficult because of time and personnel requirements. Remotely sensed elevation data, in particular that derived from airborne light-detection and ranging (LIDAR) sensors, could be used because of its extensive coverage. In 1998, a beach-fill project was carried out at Wrightsville Beach, North Carolina, and coincidentally LIDAR data were collected annually in this location from 1997 to 2000. This project uses the LIDAR data to identify beach and dune zones and to compute volumetric changes for each zone. Spatial variations are analyzed by examining shoreline segments, in which beach and dune volumes are determined for the different surveys. Spatial and temporal changes in both the beach and dune zones are monitored following the initial fill project. The passage of hurricanes Bonnie and Floyd in the ...

PRELIMINARY DATA OF TOTAL LIQUID VENTILATION IN A NORMAL FULL-SIZED SHEEP MODEL

In an effort to bring total liquid ventilation (TLV) to clinical application, a prototype ventilator with 4 single piston pumps and 4 conventional membrane oxygenators, simply designed and easily controlled, was tested in an in vivo ful- sized sheep model. TLV was performed in 3 anesthetized and paralyzed sheep (weight range 54–56 Kg). Once all the inclusion criteria were met during gas ventilation (PaO2 > 400mmHg, PaCO2 between 30–45mmHg, and MAP 60 mmHg), liquid ventilation process was started giving an initial fill volume of 30 ml/kg of pre-warmed PFC (FC77), followed by a liquid tidal volume. Respiratory rate was set as 5 breaths per minute, and an I:E ratio of 1:2 using a square wave flow pattern during both phases of ventilation was used; Arterial blood gas; hemoglobin; oxygen saturation; SvO2; cardiac output; systemic and pulmonary arterial blood pressure; heart rate; ventilator pressure, tidal volume, and airway pressure data w assessed and recorded at the beginning of TLV and then every hour. The ventilator's CO2 removal efficiency was assessed by sampling the PFC before and after the oxygenators and calculating the normalized CO2 removal efficiency by the formula: [PPFCCO2in-PPFCCO2out]/ [PPFCCO2in]. This system was tested for 3 hours with stable PaCO2 and PaO2 (see figures below) and no hemodynamic impairment. An averaged CO2 removal efficiency of 80% and an averaged level of 676 mmHg of PFC PO2 were obtained by the 4 membrane oxygenators with a countercurrent sweep gas of 100% oxygen at 5 L/min. No evidence of fluorothorax was observed at the chest gross examination at the end of the experiments; These data suggest the potential of this prototype to support removing CO2 and oxygenating perfluorocarbons during total liquid ventilation in a full sized animal model.Figure

The impact of non-compliance with imatinib (IM) therapy on health care costs

6083 Background: While compliance to drug therapy is vital to receive optimal patient benefits, the costs of delivering adequate medical care for cancer patients remain an important consideration for society and payers. This study examined the relationship between compliance with IM therapy and health care costs for patients with CML and GIST. Methods: Claims data from 6/1/01–3/31/04 from a US health plan were used to identify non-Medicare IM-treated patients with a CML or GIST diagnosis who had continuous pharmacy and medical benefits in the 3 months prior and 12 months following initiation of IM therapy. Compliance was defined by medication possession ratio (MPR=total days IM supply in the first year ÷365) and patients were stratified into three segments by MPR (<50%, 50–90%, 90–100%). Total health care costs include hospital, laboratory testing, office, ER, and pharmacy charges. Disease-related health care costs were also analyzed. Multivariate analyses were used to examine the relationship between MPR and first-year health care costs, controlling for age, sex, number of medications, initial starting dose, diagnosis (CML or GIST), year of initial IM fill, and complications due to underlying disease. Results: Total 878 IM-treated patients were identified of whom 413 had at least 15 months of continuous eligibility. Of these, 307 were non-Medicare CML or GIST patients. Total health care costs per patient in the first year of therapy in MPR < 50%, 50–90%, and 90–100% groups were $163,828, $53,924, and $40,924 respectively (p < 0.001). The corresponding numbers for disease-related health care costs were $103,118, $36,436, and $34,086 (p<0.001). Controlling for the variables listed above, a 10% increase in MPR is associated with a 5% decrease in total health care costs (p=0.021). Similar association was found between MPR and disease-related health care costs. Conclusions: Improved compliance with imatinib therapy is associated with decreased total health care costs and disease-related health care costs. Improving compliance to imatinib therapy may not only optimize clinical outcomes but may also reduce the overall societal burden of health care costs associated with cancer. [Table: see text]

Improved dust capture methods for crushing plant

The use of compressive crushing equipment such as gyratory crushers within minerals processing plants can potentially generate large quantities of dust. Remedies to this problem include the retrofitting of shrouds, enclosures, local exhaust ventilation (LEV) systems and water suppression systems. The single or combined application of these systems must be optimised to ensure they operate efficiently. It is desirable that the future design planning of such facilities include integrated dust suppression and/or removal systems to ensure material delivery rates are maintained and the welfare of the workforce is protected. The tipping of mineral ore into the crusher feed bin is investigated by the construction and solution of computational fluid dynamic (CFD) models validated by data obtained from scale experiments. A 3D computational model was constructed using the Fluent™ CFD software to represent the background ventilation regime within an underground crushing installation. The falling ore is represented as a continuum granular fluid falling under gravity from the raised bed of the dump truck. Transient path lines are computed to simulate the updraft airflow generated by the tipping process and indicate the dispersion path of any entrained dust. The relationships between the falling ore material, the displaced air and the shear induced flow are determined by an analysis of the computed volume/mass flow rates predicted across the crusher opening. A parametric study has been performed on the model of the tipping process to investigate the influence on dust dispersion of; the orientation of the dump truck, the surrounding ventilation characteristics and the material tipping rate, volume and initial fill level of the crusher bin. The operation of LEV systems has also been simulated to identify the influence of such systems on the airflow characteristics in and around the crusher feed bin. An analysis of the airflow patterns predicted by the CFD simulation models indicates strong shear flows induced between the tipped material and the surrounding airflow in the vicinity of the crusher during tipping, and a strong influence of the background ventilation regime on the path taken by this shear flow. Scale experimental studies were conducted to characterise the induced shear flow and visualise the potential entrainment and transport of dust. An analysis of these preliminary experiments is presented.

Species responsible for Si–H 2 bond formation in a-Si:H films deposited using silane high frequency discharges

Species responsible for Si–H 2 bond formation in a-Si:H films have been studied by using a cluster-suppressed plasma CVD reactor of a diode configuration. The concentration of Si–H 2 bonds in a-Si:H films linearly decreases with decreasing the volume fraction V f of clusters incorporated into the films, while the density of higher-order silane such as Si 2H 5 and Si 3H 7 correlates little with the bond concentration. The experimental results obtained using the diode configuration motivate us to employ a reactor of triode configuration in order to reduce the V f value. The a-Si:H Schottky solar cell prepared with this configuration has the high initial fill factor FF = 0.60 and high stabilized value after light soaking FF = 0.56.

Three-dimensional discrete element simulations in hoppers and silos

The initial fill and the subsequent discharge of containers containing granular material have been modeled using the discrete element method (DEM). In particular, the behavior of granular material in three dimensions is accounted for. The aim is to study the distributions of normal wall forces and pressures developed at the end of filling process (static state) and those developed during outflow from the containers (dynamic state). A hopper, a silo with a hopper bottom, and a flat-bottomed silo have been chosen for DE analysis. The granular material is modeled as a particle assembly consisting of mono-sized, spherical, cohesionless particles. Movement of individual particles during the outflow caused by gravity was also studied. The simulation results obtained in the present work are realistic and show clearly the advantages of DEM to understand the complex flow behavior of granular materials.

Hydrodynamics simulations of 2ω laser propagation in underdense gasbag plasmas

Recent 2ω laser propagation and stimulated Raman backscatter (SRS) experiments performed on the Helen laser have been analyzed using the radiation-hydrodynamics code HYDRA [M. M. Marinak, G. D. Kerbel, N. A. Gentile, O. Jones, D. Munro, S. Pollaine, T. R. Dittrich, and S. W. Haan, Phys. Plasmas 8, 2275 (2001)]. These experiments utilized two diagnostics sensitive to the hydrodynamics of gasbag targets: a fast x-ray framing camera (FXI) and a SRS streak spectrometer. With a newly implemented nonlocal thermal transport model, HYDRA is able to reproduce many features seen in the FXI images and the SRS streak spectra. Experimental and simulated side-on FXI images suggest that propagation can be explained by classical laser absorption and the resulting hydrodynamics. Synthetic SRS spectra generated from the HYDRA results reproduce the details of the experimental SRS streak spectra. Most features in the synthetic spectra can be explained solely by axial density and temperature gradients. The total SRS backscatter increases with initial gasbag fill density up to ≈0.08 times the critical density, then decreases. Data from a near-backscatter imaging camera show that severe beam spray is not responsible for the trend in total backscatter. Filamentation does not appear to be a significant factor in gasbag hydrodynamics. The simulation and analysis techniques established here can be used in ongoing experimental campaigns on the Omega laser facility and the National Ignition Facility.

A prototype of a liquid ventilator using a novel hollow-fiber oxygenator in a rabbit model.

A functional total liquid ventilator should be simple in design to minimize operating errors and have a low priming volume to minimize the amount of perfluorocarbon needed. Closed system circuits using a membrane oxygenator have partially met these requirements but have high resistance to perfluorocarbon flow and high priming volume. To further this goal, a single piston prototype ventilator with a low priming volume and a new high-efficiency hollow-fiber oxygenator in a circuit with a check valve flow control system was developed. Prospective, controlled animal laboratory study. Research facility at a university medical center. Seven anesthetized, paralyzed, normal New Zealand rabbits The prototype oxygenator, consisting of cross-wound silicone hollow fibers with a surface area of 1.5 m2 with a priming volume of 190 mL, was tested in a bench-top model followed by an in vivo rabbit model. Total liquid ventilation was performed for 3 hrs with 20 mL.kg(-1) initial fill volume, 17.5-20 mL.kg(-1) tidal volume, respiratory rate of 5 breaths/min, inspiratory/expiratory ratio 1:2, and countercurrent sweep gas of 100% oxygen. Bench top experiments demonstrated 66-81% elimination of CO2 and 0.64-0.76 mL.min(-1) loss of perfluorocarbon across the fibers. No significant changes in PaCO2 and PaO2 were observed. Dynamic airway pressures were in a safe range in which ventilator lung injury or airway closure was unlikely (3.6 +/- 0.5 and -7.8 +/- 0.3 cm H2O, respectively, for mean peak inspiratory pressure and mean end expiratory pressure). No leakage of perfluorocarbon was noted in the new silicone fiber gas exchange device. Estimated in vivo perfluorocarbon loss from the device was 1.2 mL.min(-1). These data demonstrate the ability of this novel single-piston, nonporous hollow silicone fiber oxygenator to adequately support gas exchange, allowing successful performance of total liquid ventilation.

Development and validation of a material-labeling method for powder process characterization using X-ray computed tomography

The material-labeling method presented in this paper, coupled with X-ray computed tomography (XRCT), allows in situ non-invasive 3D characterization of certain pharmaceutical processes using relevant materials and process geometry. Microcrystalline cellulose (MCC, Celphere) particles were used in experiments, and lead (II) acetate trihydrate was used to label the MCC particles because it has both high water solubility and high X-ray attenuation coefficient. A 0.5-M lead acetate solution was used to impregnate the Celphere particles, and thus to deliver sufficient contrast in the XRCT shadow images. Selected physical properties of the impregnated particles were examined and found to be similar to the as-received material. The mixture of Pb-impregnated and as-received Celphere particles constituted a model pharmaceutical system to investigate die compaction and blending. Lead impregnation allows particles of low atomic weight to become visually traceable on XRCT by enhancing their X-ray absorption. For the compaction study, the in-die positions of Pb-impregnated particles were monitored as a function of compaction pressure. For the mixing study, a linear correlation between the gray scale of the cross-section images and the percentage of Pb-impregnated particles in the mixture was demonstrated. Two different initial fill configurations were compared: column-filling and layer-filling. Results show that the layer-filled configuration leads to better mixing than the column-filled configuration.