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Author: Publisher: ISBN: Category : Languages : en Pages :
Book Description
Knowledge of the rheological properties of non-Newtonian fluids is critical for modeling in polymer-processing equipment such as injection molders, extruders, and blow molders. Rheological measurements can be obtained through standard flows, such as shear flow and elongational flow. In our research, we modeled the rheological properties of polymeric fluids in several types of experiments: transient and steady shear flow, small amplitude oscillatory shear flow, transient elongational flow, and step-strain shear flow. The accuracy of modeling calculations depends critically on the performance of the rheological model used. Differential constitutive models with a single relaxation time can be used for exploratory fluid dynamics research and provide insight into the qualitative effects of viscoelasticity in complex flow fields. However, differential models with a single relaxation time give a poor quantitative description of rheological properties, since most non-Newtonian media exhibit not just one, but a whole spectrum of relaxation times; therefore multiple relaxation modes models were used in our research. One of the coupled linear relaxation models, the Two Coupled Maxwell Modes (TCMM) Model, was used to describe quantitatively shear-thickening behavior, which can be observed under certain conditions for high molecular weight polymers dissolved in low viscosity solvents. In this case, the shear viscosity of the polymer solution increases with increasing shear rate. A full parameterization of the TCMM Model to the experimental data from the literature provided a thorough understanding of the significance of the model parameters and a clear insight into the peculiar behavior of shear thickening in dilute polymer solutions. The primary part of the research focused on models with linear springs. A typical, industrial-grade, low-density polyethylene polymer was studied using three types of multi-mode models: i) uncoupled linear relaxation models; ii) coupled linear relaxation models; iii) uncoupled non-linear relaxation models. The data from small amplitude oscillatory shear flow and steady shear flow were fitted to obtain the parameters of the different models using the Nelder and Mead Downhill Simplex method. Then the predictions for the other standard flows mentioned in the first paragraph were compared with experimental data. This allowed us to determine the degree of the performance of the different models with regards to the corresponding system studied. Overall evaluations of model performance were presented in detail. Finally, we tested the effects of spring type on the performance of the models described above. We replaced the linear elastic springs in all of the prior models with nonlinear springs to determine whether this would improve model performance in elongational flow. The Finitely-Extensible Nonlinear Elastic Spring Model was used to describe the nonlinear elastic springs. The result was negative, however: no improvement was obtained over the linear spring models and more parameters were present which required further fitting to experimental data.
Author: Publisher: ISBN: Category : Languages : en Pages :
Book Description
Knowledge of the rheological properties of non-Newtonian fluids is critical for modeling in polymer-processing equipment such as injection molders, extruders, and blow molders. Rheological measurements can be obtained through standard flows, such as shear flow and elongational flow. In our research, we modeled the rheological properties of polymeric fluids in several types of experiments: transient and steady shear flow, small amplitude oscillatory shear flow, transient elongational flow, and step-strain shear flow. The accuracy of modeling calculations depends critically on the performance of the rheological model used. Differential constitutive models with a single relaxation time can be used for exploratory fluid dynamics research and provide insight into the qualitative effects of viscoelasticity in complex flow fields. However, differential models with a single relaxation time give a poor quantitative description of rheological properties, since most non-Newtonian media exhibit not just one, but a whole spectrum of relaxation times; therefore multiple relaxation modes models were used in our research. One of the coupled linear relaxation models, the Two Coupled Maxwell Modes (TCMM) Model, was used to describe quantitatively shear-thickening behavior, which can be observed under certain conditions for high molecular weight polymers dissolved in low viscosity solvents. In this case, the shear viscosity of the polymer solution increases with increasing shear rate. A full parameterization of the TCMM Model to the experimental data from the literature provided a thorough understanding of the significance of the model parameters and a clear insight into the peculiar behavior of shear thickening in dilute polymer solutions. The primary part of the research focused on models with linear springs. A typical, industrial-grade, low-density polyethylene polymer was studied using three types of multi-mode models: i) uncoupled linear relaxation models; ii) coupled linear relaxation models; iii) uncoupled non-linear relaxation models. The data from small amplitude oscillatory shear flow and steady shear flow were fitted to obtain the parameters of the different models using the Nelder and Mead Downhill Simplex method. Then the predictions for the other standard flows mentioned in the first paragraph were compared with experimental data. This allowed us to determine the degree of the performance of the different models with regards to the corresponding system studied. Overall evaluations of model performance were presented in detail. Finally, we tested the effects of spring type on the performance of the models described above. We replaced the linear elastic springs in all of the prior models with nonlinear springs to determine whether this would improve model performance in elongational flow. The Finitely-Extensible Nonlinear Elastic Spring Model was used to describe the nonlinear elastic springs. The result was negative, however: no improvement was obtained over the linear spring models and more parameters were present which required further fitting to experimental data.
Author: Y.G. Yanovsky Publisher: Springer Science & Business Media ISBN: 9401121168 Category : Science Languages : en Pages : 309
Book Description
The present book is devoted to a rapidly developing field of science which studies the behavior of viscoelastic materials under the influence of deformation~the rheology of polymers. Rheology has long been treated as the theoretical foundation of polymer processing, and from this standpoint it is difficult to overesti mate its importance in practice. Rheology plays an important role in developing our ideas on the nature of viscoelastic behavior in connection with the structural features of polymers and composites based on them. This expands the possibilities of employing rheological methods to characterize a variety of materials and greatly magnifies the interest in this field of research. The rheological properties of polymer systems are studied experimen tally, chiefly under conditions of shear and tensile strains. One explana tion is that many aspects of polymer material processing are associated with the stretching of melts or a combination of shear and tensile strains. In scientific investigations, either periodic or continuous conditions of shear deformation are employed. Each mode provides widespread infor mation. In periodic deformation, most attention is generally given to conditions with low deformation amplitudes that do not alter the structure of the polymer system during an experiment (the region of linear deformation conditions). Here the viscoelastic parameters are generally determined with respect to the frequency. Continuous deforma tion involves considerable strains, and may be attended by significant reversible and irreversible changes in the structure of a polymer.
Author: Jose Luis Rivera Armenta Publisher: BoD – Books on Demand ISBN: 1789840015 Category : Science Languages : en Pages : 186
Book Description
Rheology is the science that studies the behavior of the flow of matter in a liquid state or soft solids under the application of stress or deformation to obtain a response to an applied force. In polymers, rheology is an important tool to understand behavior under processing conditions and to design equipment. Another application for rheology in the polymer field is to understand structure-property relationships by means of molecular weight, molecular weight distribution, stereochemistry, morphology, melt degradation, and performance under processing. This book covers the essential criteria for selecting the best test types for various applications and new developments, for accurately interpreting results, and for determining other areas where rheology and rheological phenomena may be useful in your work.
Author: Rupesh Bhatia Publisher: ISBN: Category : Languages : en Pages : 202
Book Description
An experimental study has been conducted to understand the rheological behavior of several non-newtonian polymeric liquids. A constant stress/strain rheometer with cone and cylinder geometry is used to determine the variation of shear stress (and hence apparent viscosity) with shear rate. A number of non-newtonian polymeric liquids that consist of carefully prepared aqueous solutions of Hydroxyethylcellulose (HEC), Polyethyleneoxide (PEO), Carboxymethylcellulose (CMC), Xanthan gum, and Polyacrylic acid (Carbopol) are used in this study. In order to ascertain the effect of molecular mass of the polymers on the apparent viscosity variation with shear rate, different grades of each polymer are used. The tests are done for varying concentrations and temperatures (23-80 deg C) to determine their requisite effects on rheology. Also, intrinsic viscosity of each polymeric liquid is obtained by using an Ubbelohde capillary tube viscometer. This characterizes the inherent capacity of each polymer to alter its solutions viscosity. Depending upon the polymer and its concentration, the results show both shear-thinning behavior with shear rate as well as time-dependent (thixotropy) effects. Time-dependent effects, which are found to be a strong function of concentration and temperature, are evaluated by measuring viscosity by first increasing and successively decreasing the shear rates. The zero-shear viscosity and shear-thinning effects are seen to decrease with concentration. In general for most polymers, high temperatures decrease the viscosity of the solution, with the exception of Carbopol for which the viscosity is seen to increase slightly with temperature and then decrease at even higher temperatures. Carbopol polymers also show thixotropic effects at higher temperatures which are significant at 80 deg C. They further exhibit yield stress at higher concentrations and no yield stress is noticed at lower concentrations. A number of models described in the literature are used to fit the rheological data. It is noticed that the modified power-law model, Sisko model and Herschel Bulkley model are insufficient approximations of the asymptotic forms and hence, could not be used to describe the rheological behavior of all the polymers. The appropriately modified and redefined asymptotic forms of all these models are used to correctly fit the data for various polymers. The variation of the different model parameters with changes in concentration and temperature are quantified, and a detailed comparative study on the effects of molecular mass, concentration, and temperature on rheological properties is presented.
Author: Crispulo Gallegos Publisher: EOLSS Publications ISBN: 1848263198 Category : Economic development Languages : en Pages : 498
Book Description
Rheology is a component of Encyclopedia of Chemical Sciences, Engineering and Technology Resources in the global Encyclopedia of Life Support Systems (EOLSS), which is an integrated compendium of twenty Encyclopedias. Rheology is the study of the flow of matter. It is classified as a physics discipline and focuses on substances that do not maintain a constant viscosity or state of flow. That can involve liquids, soft solids and solids that are under conditions that cause them to flow. It applies to substances which have a complex molecular structure, such as muds, sludges, suspensions, polymers and other glass formers, as well as many foods and additives, bodily fluids and other biological materials. The theme on Rheology focuses on five main areas, namely, basic concepts of rheology; rheometry; rheological materials, rheological processes and theoretical rheology. Of course, many of the chapters contain material from more than one general area. Rheology is an interdisciplinary subject which embraces many aspects of mathematics, physics, chemistry, engineering and biology. These two volumes are aimed at the following five major target audiences: University and College students Educators, Professional practitioners, Research personnel and Policy analysts, managers, and decision makers and NGOs.
Author: R. Byron Bird Publisher: Wiley-Interscience ISBN: Category : Science Languages : en Pages : 680
Book Description
This revision of an introductory text examines Newtonian liquids and polymer fluid mechanics. It begins with a review of the main ideas of fluid dynamics as well as key points of Newtonian fluids.
Author: Howard A. Barnes Publisher: Elsevier ISBN: 9780444871404 Category : Science Languages : en Pages : 214
Book Description
This text introduces the subject of rheology in terms understandable to non-experts and describes the application of rheological principles to many industrial products and processes.
Author: R. Byron Bird Publisher: Wiley-Interscience ISBN: 9780471518440 Category : Technology & Engineering Languages : en Pages : 1086
Book Description
This two-volume work is detailed enough to serve as a text and comprehensive enough to stand as a reference. Volume 1, Fluid Mechanics, summarizes the key experiments that show how polymeric fluids differ from structurally simple fluids, then presents, in rough historical order, various methods for solving polymer fluid dynamics problems. Volume 2, Kinetic Theory, uses molecular models and the methods of statistical mechanics to obtain relations between bulk flow behavior and polymer structure. Includes end-of-chapter problems and extensive appendixes.
Author: 
Author: 
Author: Y.G. Yanovsky
Author: Jose Luis Rivera Armenta
Author: Rupesh Bhatia
Author: Crispulo Gallegos
Author: R. Byron Bird
Author: 
Author: Howard A. Barnes
Author: R. Byron Bird
Author: Chang Dae Han