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Computer aided modeling and analysis of the human skull for varied impact loadsPatel, Jayesh V. January 1993 (has links)
No description available.
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Computer aided modeling of proteins and prediction of their 3-D structure using neural networksVij, Lokesh January 1993 (has links)
No description available.
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Accuracy and reliability of traditional measurement techniques for tooth widths and arch perimeter compared to CAD/CAMElmubarak, Mona January 2018 (has links)
>Magister Scientiae - MSc / Background: Plaster models form an integral part of the traditional orthodontic
records. They are necessary for diagnosis and treatment planning, case presentations
as well as for the evaluation of treatment progress. The accuracy of the measurements
taken for space assessment is crucial prior to treatment planning. The introduction of
digital models overcomes some problems experienced with plaster models. Digital
models have shown to be an acceptable alternative for plaster models.
Aim: The aim of the study was to determine the accuracy of traditional measurement
techniques when compared to the CAD/ CAM measurements in the assessment of
tooth widths and arch perimeter from plaster models.
Method: The mesio-distal tooth widths and arch perimeter of thirty archived plaster
models were measured using a digital caliper to the nearest 0.01 mm and divider to
the nearest 0.1 mm. Corresponding digital models were produced by scanning them
with a CAD/CAM (InEos X5) and space analysis completed by measurements using
InEos Blue software. Measurements were repeated after 1 week from the initial
measurement. The methods were compared using descriptive analysis (mean
difference and standard deviation).
Results: The operator reliability was high for digital models as well as the plaster
models when the measurement tool was the digital caliper (analyzed using the
Pearson correlation coefficient in the paired t-test). The mean values of tooth widths
measurements of CAD/CAM, digital caliper and divider were 6.82 (±0.04), 6.94 (±
0.04) and 7.11 (± 0.04). There was a significant difference between the measurements
made by the CAD/CAM and the divider. Additionally significant differences between
the measurements by digital caliper and divider measurements (p < 0.05) were
observed. No significant difference was found when comparing CAD/CAM to digital
caliper. Positive correlation was displayed between CAD/CAM, digital caliper and the
divider, but the measurements completed with the digital caliper had the highest
correlation with the CAD/CAM. The difference was not significant between the
aforementioned measurement tools (p > 0.05). Arch perimeter measurements showed
no statistical significant difference between CAD/CAM, digital caliper and divider (p
< 0.05).
Conclusion: Archived plaster models stored as records can be converted to digital
models as it will have the same accuracy of measurements. The value of doing a space
analysis with the CAD/CAM system can be performed with similar reliability on the
digital models as a caliper on plaster models.
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Computer-aided modeling and simulation of molecular systems and protein secondary structure predictionSoni, Ravi January 1993 (has links)
No description available.
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Computer-aided modeling and simulation of molecular systems and protein (WT-bGH) structure minimizationHuang, Zheng January 1995 (has links)
No description available.
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Computer Aided Simulation and Process Design of a Hydrogenation Plant Using Aspen HYSYS 2006Ordouei, Mohammad Hossein January 2009 (has links)
Nowadays, computers are extensively used in engineering modeling and simulation fields in many different ways, one of which is in chemical engineering. Simulation and modeling of a chemical process plant and the sizing of the equipment with the assistance of computers, is of special interests to process engineers and investors. This is due to the ability of high speed computers, which make millions of mathematical calculations in less than a second associated with the new powerful software that make the engineering calculations more reliable and precise by making very fast iterations in thermodynamics, heat and mass transfer calculations. This combination of new technological hardware and developed software enables process engineers to deal with simulation, design, optimization, control, analysis etc. of complex plants, e.g. refinery and petrochemical plants, reliably and satisfactorily.
The main chemical process simulators used for static and dynamic simulations are ASPEN PLUS, ASPEN HYSYS, PRO II, and CHEMCAD. The basic design concepts of all simulators are the same and one can fairly use all simulators if one is expert in any of them.
Hydrogenation process is an example of the complex plants, to which a special attention is made by process designers and manufacturers. This process is used for upgrading of hydrocarbon feeds containing sulfur, nitrogen and/or other unsaturated hydrocarbon compounds. In oil and gas refineries, the product of steam cracking cuts, which is valuable, may be contaminated by these unwanted components and thus there is a need to remove those pollutants in downstream of the process. Hydrogenation is also used to increase the octane number of gasoline and gas oil.
Sulfur, nitrogen and oxygen compounds and other unsaturated hydrocarbons are undesired components causing environmental issues, production of by-products, poisoning the catalysts and corrosion of the equipment. The unsaturated C=C double bonds in dioleffinic and alkenyl aromatics compounds, on the other hand, cause unwanted polymerization reactions due to having the functionality equal to or greater than 2.
Hydrogenation process of the undesired components will remove those impurities and/or increase the octane number of aforementioned hydrocarbons. This process is sometimes referred to as “hydrotreating”; however, “upgrader” is a general word and is, of course, of more interest.
In this thesis, a hydrogenation process plant was designed on the basis of the chemistry of hydrocarbons, hydrogenation reaction mechanism, detailed study of thermodynamics and kinetics and then a steady-state simulation and design of the process is carried out by ASPEN HYSYS 2006 followed by design evaluation and some modifications and conclusions.
Hydrogenation reaction has a complicated mechanism. It has been subjected to hot and controversial debates over decades. Many kinetic data are available, which contradict one another. Among them, some of the experimental researches utilize good assumptions in order to simplify the mechanism so that a “Kinetic Reaction” modeling can be employed. This thesis takes the benefit of such research works and applies some conditions to approve the validity of those assumptions.
On the basis of this detailed study of reaction modeling and kinetic data, a hydrogenation plant was designed to produce and purify over 98 million kilograms of different products; e.g. Benzene, Toluene, Iso-octane etc. with fairly high purity.
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Computer Aided Simulation and Process Design of a Hydrogenation Plant Using Aspen HYSYS 2006Ordouei, Mohammad Hossein January 2009 (has links)
Nowadays, computers are extensively used in engineering modeling and simulation fields in many different ways, one of which is in chemical engineering. Simulation and modeling of a chemical process plant and the sizing of the equipment with the assistance of computers, is of special interests to process engineers and investors. This is due to the ability of high speed computers, which make millions of mathematical calculations in less than a second associated with the new powerful software that make the engineering calculations more reliable and precise by making very fast iterations in thermodynamics, heat and mass transfer calculations. This combination of new technological hardware and developed software enables process engineers to deal with simulation, design, optimization, control, analysis etc. of complex plants, e.g. refinery and petrochemical plants, reliably and satisfactorily.
The main chemical process simulators used for static and dynamic simulations are ASPEN PLUS, ASPEN HYSYS, PRO II, and CHEMCAD. The basic design concepts of all simulators are the same and one can fairly use all simulators if one is expert in any of them.
Hydrogenation process is an example of the complex plants, to which a special attention is made by process designers and manufacturers. This process is used for upgrading of hydrocarbon feeds containing sulfur, nitrogen and/or other unsaturated hydrocarbon compounds. In oil and gas refineries, the product of steam cracking cuts, which is valuable, may be contaminated by these unwanted components and thus there is a need to remove those pollutants in downstream of the process. Hydrogenation is also used to increase the octane number of gasoline and gas oil.
Sulfur, nitrogen and oxygen compounds and other unsaturated hydrocarbons are undesired components causing environmental issues, production of by-products, poisoning the catalysts and corrosion of the equipment. The unsaturated C=C double bonds in dioleffinic and alkenyl aromatics compounds, on the other hand, cause unwanted polymerization reactions due to having the functionality equal to or greater than 2.
Hydrogenation process of the undesired components will remove those impurities and/or increase the octane number of aforementioned hydrocarbons. This process is sometimes referred to as “hydrotreating”; however, “upgrader” is a general word and is, of course, of more interest.
In this thesis, a hydrogenation process plant was designed on the basis of the chemistry of hydrocarbons, hydrogenation reaction mechanism, detailed study of thermodynamics and kinetics and then a steady-state simulation and design of the process is carried out by ASPEN HYSYS 2006 followed by design evaluation and some modifications and conclusions.
Hydrogenation reaction has a complicated mechanism. It has been subjected to hot and controversial debates over decades. Many kinetic data are available, which contradict one another. Among them, some of the experimental researches utilize good assumptions in order to simplify the mechanism so that a “Kinetic Reaction” modeling can be employed. This thesis takes the benefit of such research works and applies some conditions to approve the validity of those assumptions.
On the basis of this detailed study of reaction modeling and kinetic data, a hydrogenation plant was designed to produce and purify over 98 million kilograms of different products; e.g. Benzene, Toluene, Iso-octane etc. with fairly high purity.
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Modelování interakcí cytochromů P450 s flavodoxinem / Interaction of Cytochromes P450 with Flavodoxin: a theoretical studyCulka, Martin January 2013 (has links)
Cytochromes P450 are diverse group of heme enzymes found in most species on Earth. In humans they are involved in metabolism of foreign compounds or steroids, bacteria employ cytochromes P450 for utilization of various hydrophobic substrates. General reaction catalyzed by cytochromes P450 is monooxygenation, when one atom of oxygen molecule is introduced into the substrate, while the other is reduced producing water. NADPH:cytochrome P450 oxidoreductase or cytochrome b5 usually serves as an electron donor providing electrons needed for activation of oxygen in eukaryotic organisms, in bacteria small FeS proteins or flavoproteins are these electron donors. It was shown earlier that bacterial electron donor flavodoxin could also interact with human cytochromes P450 in vitro. This thesis employs molecular modeling techniques to support a hypothesis that flavodoxin is responsible for reduction of human (1A2, 2A6, 2A13, 2C9, 2C19, 3A4) and bacterial (101A1 a 176A1) cytochromes P450 heterologously expressed in Escherichia coli. An initial guess of possible mutual orientations of cytochrome P450 and flavodoxin was predicted using information-driven protein-protein docking. The stability of these complexes was examined by directed dissociation method. The most stable orientation for each cytochrome P450 was further...
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