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Professor Jāzeps Boļšijs
Course description: 10Credit units; 32 hours lectures
Control forms: Exam
Course content:
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The glassy state of a substance.
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Viscosity and the process of glass forming. Crystalline compounds and the ability to form glass. The stabilized state of glass. The forming and crystallization of glass - antagonistic processes.
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The structure of silicate glasses.
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Thermal phenomena in glass.
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An ability to crystallize, density, optical, electrical, mechanical and other properties of glass. The influence of various components on the properties of glass : SiO2, oxides of elements of the first, second, third and fourth groups, of elements with variable valency and oxides of rare earths.
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Components of semi-conductoring, photoirritable, optically transparent and other special glasses.
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Flux, refreshers, mufflers and other important additions in the glass technology.
Literature:
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Fggty F.F. {bvbz cntrkf. K.% {bvbz> Ktybyuh.jnlybt> 1974> 351 c.
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Oel H.J., Schaeffer H.A. Glas: Letfaden zur Vorlesung. Glas und Keramik II. - Erlangen, 1970. Bibliogr.: 47 ref.
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Schaeffer H.A., Heussner K.H. Technologie des Glases. - Erlangen: Instit. für Werkstoffwissenschaften, 1990, 306 s.
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Boļšijs J. Stikla ķīmija un tehnoloģija. Lekciju konspekts. RTU: SMI, 1997, 78 lpp.
Chemical technology of tradicional and new ceramics
ĶST 672
Asociētā profesore Gaida-Maruta Sedmale
Course description: 10Credit units; 32 hours lectures
Control forms: Exam.
Course content:
Aim: to give the knowledge to the students of connection between structure, properties and technology of ceramics.
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Characteristics of tradicional and new ceramics: differences in compositions and technologies.
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Structure: the form of joining (atom-, ionjoining, other), crystals; silicates (systematic, cryterion of stability, modifications of SiO2, important layer silicates). Amorphous substance: glasses (structure, properties). Joining of boundary formation, formation of compound.
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Thermochemistry, thermodynamic phases equilibrium (phase bill, diagramme), kinetic (melting - crystallisation, diffusion, reaction, sintering).
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Important systems for ceramics.
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Properties: thermal, mechanical, electrical, magnetical, optical, chemical.
Literature:
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Salmang-Scholze. Keramik. Teil1. Springler Verlag,1983, 308 S.
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E.Krause,I.Berger u.a. Technologie der Keramik.Band1. VEB Verlag für Bauwesen, Berlin, 278 S.
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E.L.Rbyuthb. Ddtltybt d rthfvbre> Vjcrdf> 1967> 549 cnh.
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F.F.Rhegf. {bvbxtcrfz nt[yjkjubz rthfvbxtcrb[ vfnthbfkjd> Rbtd> 1990> 399cnh.
Technology and equipment of biomaterials
KST 679
Assistant Professor Rūdolfs Cimdiņš
Course description: 10Credit units; 32 hours lectures
Control forms: Exam
Course content:
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Basic technologies of biomaterials production: technology of metals, technologies of glass and ceramics, technologies of biopolymers and composite materials.
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Influence of technologies to structure and properties of biomaterials.
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The polylayer bioactive coatings output of background.
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Interaction of materials during of output process. Influence of technological operation to ready implant properties.
Literature:
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Larry l.Hench, June Wilson. An Introduction to Bioceramics, Advanced Series in Ceramics. Vol.1, Hong Kong, 1993, 386.
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G.Heimke. Bioceramics. Vol.2, Heidelberg, Germany, 1990.
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Ö.H.Andersson, R.P.Happanen, A.Y.Urpo. Bioceramics. Vol.7, Turku, Finland, Butterworth Heinemann, 1994.
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H.Blumennauer. Werkshtoffprüfung. Deutscher Verlag für Grundstoffindustrie, Leipzig, Stuttgart, 1976.
Biocompability of materials KST 680
Assistant proffesor Līga Bērziņa
Course description: 10Credit units; 32 hours lectures
Control forms: Exam
Course content:
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Biocompability in vivo environment. The choice of laboratory animals and implantation technique according to the properties, dimensions and planned usage of the implant in the clinic.
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The effect of body on the material. The effect of the material on teh body. The tests of biomaterials before, during and after the implantation.
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Biocompability tests. Bioactivity.
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Biomaterials for stomatology (dental biomaterials, kinds of biomaterials, properties), plastic surgery (medical, biological, surgical and esthetic requirements to the biomaterials), cardiovascular surgery and orthopaedy.
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Drug delivery systems.
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Natural bimaterials.
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Standards and test methods.
Literature:
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E.Wintermantel, S.W.Ha. Biocompatible Werkstoffe und Bauweisen, Implantate für Medizin und Umvelt, Springers - Verlag Berlin Heidelberg, 1998.
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Materials in Medicine. Edit. M.O.Speidel, P.J.Uggowitzer, Hochschulvalag AG under ETH Zürich.
Chemical Process Modeling
ĶVT 641
Assistant Professor Ilo Dreijers
Course description: 10Credit units; 32 hours lectures
Control forms: Exam
Course content:
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Types of matematical models, classification.
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Laplass transformation, complex plane models. residence time distribution models and transfer functions.
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Transfer functions for combined models.
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Identification of parameters and adequacy.
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Numerical methods for nonlinear algebraic and differencial equations.
Literature:
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W.L. Luben. Process Modeling, Simulation and Control for Chemical Engineers. McGrawHill,1990. 725 pg.
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M.M. Denn. Process Modeling. Longman Scientific, 1987. 321 pg.
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В.В. Кафаров, И Н Дорохов. Системный анализ процессов химической технологии. М., Нaука, 1976.
Theoretical Principles of Chemical Engineering
ĶVT 642
Assistant Professor Ilo Dreijers
Course description: 10Credit units; 32 hours lectures
Control forms: Exam
Course content:
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Modeling basics, classification of models, systems, elements, and hierarchy.
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Material and heat balances for steady state processes.
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Balance equation system analysis and solving.
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Flow diagrams: serial and parallel connection, bypass, purge, recycle. Decomposition of flow sheet.
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Residence Time Distribution (RTD) models: ideal mixing, plug flow, longitudinal diffusion, combined RTD models, model parameter estimation.
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Problem solving using QuickBasic, Eureka, Matlab.
Literature:
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I. Dreijers. Kompjūteri ķīmijas tehnoloģijā. Rīga: RTU, 1992. 211 lpp.
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I. Dreijers, I. Riekstiņa. Inženierķīmiskie modeļi un skaitliskās metodes. Laboratorijas praktikums. Rīga: RTU. 1996. 134 lpp.
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I. Dreijers, P. Vītols. Ķīmijas tehnoloģijas teorētiskie pamati. Rīga:224 lpp.
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Roger G. E. Franks. Modeling and Simulation in Chemical Engineering. Wiley-Interscience, 1972. 409 pg.
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Morton M. Denn. Process Modeling. Longman Scientific & Technical, 1986. 321 pg.
Process Simulation
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