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Model material

Model (material) parameters used in viscoelastic constitutive equations... [Pg.9]

Model Material hulk density, Ih/ft Approx- imate capacity, tons/h Size (width X length), ft Plate thick- ness, in shaft diam- eter, in Speed, r/min Drive, hp... [Pg.1894]

POLYMERIC ALLOYS MODEL MATERIALS FOR THE UNDERSTANDING OF THE STATISTICAL THERMODYNAMICS OF MIXTURES... [Pg.197]

The material composition of the model (material model) whieh states what portion of... [Pg.4]

FIG. 72. Schematic cross-section of (a) a single junction p-i-n o-Si H superstrata solar cell and (b) a tandem solar cell structure. (From R. E. I, Schropp and M. Zeman. "Amorphous and Microcrystalline Silicon Solar Cells—Modeling, Materials and Device Technology," Kluwer Academic Publishers, Boston, 1998, with permission.)... [Pg.170]

R. E. I. Schropp and M. Zeman, Amorphous and Microcrystalline Silicon Solar Cells—Modeling, Materials and Device Technology. Kluwer Academic Publishers, Boston, 1998. [Pg.191]

Large zeolite crystals with dimensions of tens and hundreds of micrometers have proven to be irreplaceable as model materials for reactivity and diffusion studies in the field of zeolite science and heterogeneous catalysis [1-3], These large crystallites often possesses complex structures consisting of several intergrown subunits and since the pore orientations of the different elements are not always aligned, this phenomenon can have a considerable effect on the accessibility of the pores in different crystallite regions [4]. [Pg.5]

Fe(btr)2(NCS)2]-H20 undergoes a complete ST centred at 134 Kwith a hysteresis loop of width 21 K. This derivative represents the first example of a 2D ST compound and has become a model material in SCO research. The presence of a crystallographic phase transition to account for the observed hysteresis was first proposed since crystal cracking was regularly observed when the sample was cooled through the temperature region of the spin transition [59]. Recent X-ray data recorded at 95 K, where the com-... [Pg.254]

Aggregates are microprecipitates of tens to thousands of polymer molecules which can be invisible to the naked eye or appear as a faint cloudiness in the solution. They form when a poor solvent such as methanol is added to a molecularly dispersed solution of the polymer in a good solvent, such as toluene or THF, or vice versa. Since aggregates are the first stage of a solid precipitate, they are also useful as model materials of the solid bulk state polymers and are amenable to study by many solution techniques such as solution-state UV and CD spectroscopy. Chiral molecules... [Pg.625]

Here is the element viscosity, is the element modulus, and Ay is the relaxation time. If this model material is placed in a constant stress environment for a fixed time and then the stress is removed, then the time-dependent strain will have the recovery characteristics shown in Fig. 3.11. [Pg.74]

Only Smith and Nienow (1983a) have reported a systematic investigation of the effects of gas velocity on granule size and on particle growth mechanisms. These authors used model materials (non-porous... [Pg.155]

Zeman M, Schropp REI (1998) Amorphous and microcrystalline silicon solar cells Modeling, materials and device technology, Kluwer Academic Publishers, Dordrecht,... [Pg.513]

Huang C (1974) Plysicochemical studies of collagen and collagen-mucopolysaccharide composite materials (model materials for skin). Sc.D. Thesis, Massachusetts Institute of Technology, Cambridge MA... [Pg.243]

Is one model scale sufficient or should tests be carried out in models of different sizes One model scale is sufficient if the relevant numerical values of the dimensionless numbers necessary to describe the problem (the so-called process point in the pi space describing the operational condition of the technical plant) can be adjusted by choosing the appropriate process parameters or physical properties of the model material system. If this is not possible, the process characteristics must be determined in models of different sizes, or the process point must be extrapolated from experiments in technical plants of different sizes. [Pg.21]

We have to realize that sometimes requirements concerning physical properties of model materials exist that cannot be implemented. In such cases only a partial similarity can be realized. For this, essentially only two procedures are available (for details see Refs. 5 and 10). One consists of a well-planned experimental strategy in which the process is divided into parts, which are then investigated separately under conditions of complete similarity. This approach was first applied by William Froude (1810-1879) in his efforts to scale-up the drag resistance of the ship s hull. [Pg.22]

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See also in sourсe #XX -- [ Pg.91 ]

See also in sourсe #XX -- [ Pg.348 ]



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Ab Initio Modeling of Materials

Biodegradation modelling composite materials made

Composite materials biodegradation modelling

Composite materials modelling with defects

Composite materials, modeling

Computational fluid dynamics materials processing modeling using

Computational mechanics material models

Computer modeling material balance problems

Copyrighted material models

Creep behavior material models

Currently Available Material Models

Cylindrical-material model

Cylindrical-material model finite-element analysis

Dispersion model material balance

Double fracture model materials

Electrons, crystalline solid materials energy band model

Equilibrium model for organic materials

Finite element modeling materials

Finite element modelling materials

Finite energy modelling material properties

High-surface-area materials, model

Higher Order FDTD Modeling of Boundaries and Material Interfaces

Ionic Interaction Models for MX2 Glass-Forming Materials

Linear elastic material model

Material Removal Model

Material balance equations, mass transfer model

Material behavior computer modeling

Material flow model

Material modeling hybrid model

Material modeling hyperelasticity

Material modeling isotropic -plasticity

Material modeling linear elasticity

Material modeling linear viscoelasticity

Material models elastic materials

Material models elastoplastic materials

Material models viscoplastic materials

Material models, development

Material removal mechanism thermal model

Materials Properties for Modeling Planetary Formation

Materials and Methods Model Complexes

Materials modeling QSPR/QSAR

Materials modeling continuum models

Materials modeling finite element methods

Materials modeling neural networks

Materials modeling statistical correlations

Materials processing, computation fluid dynamics modeling

Mathematical model material balances

Mathematical modeling, blood-materials

Mathematical modelling of chemical migration from food contact materials

Mechanics of materials model

Mesoscale materials modeling

Model (material) parameters used in viscoelastic constitutive equations

Model Input Material Property Parameters

Modeling material

Modeling of Materials

Modeling the Self Assembly of Ternary Blends that Encompass Photosensitive Chemical Reactions Creating Defect-Free, Hierarchically Ordered Materials

Modelling Complex Materials

Modelling of carbon-based materials for hydrogen storage

Multiscale Materials Modeling

Nanoscale materials modeling

Numerical Modeling of Multiphase Flows in Materials Processing

Pi-space and Requirements Concerning the Model Material System

Plastic materials, mathematical modeling

Polymeric materials Polymerization, modeling

Porous materials modeling pore structure

Porous materials models

Porous materials simple geometric model

Porous materials thermodynamic models

Prediction of diffusion coefficients in gases, liquids, amorphous solids and plastic materials using an uniform model

Predictive material models

Protein-based materials Elastic model proteins

Reference standard material Regression model

Relevance of Model Compounds to Electrode Materials

Shear thinning materials cross model

Sorbent materials, surface model

Spherical-material model

Statistical Mechanics Models for Materials

Structural materials polycrystalline modeling

Subject materials modelling

Subject modelling complex materials

The behaviour of model materials in creep tests

Thermodynamics and materials modelling

Viscous material Kelvin model

Viscous material Maxwell model

Viscous material mechanical model

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