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Continuous solid state extrusion of polytetrafluoroethylene below its normal atmospheric melting point of 342C̊McGee, Robert Lee. January 1984 (has links)
Thesis (M.S.)--Ohio University, March, 1984. / Title from PDF t.p. Title on abstract: Continuous solid state ram extrusion of polytetrafluoroethylene below its normal atmospheric melting poing of 342C̊.
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Graft polymerization of methyl methacrylate onto polytetrafluoroethylene free radicalsDonato, Karen Ann. January 1985 (has links)
Thesis (M.S.)--Ohio University, November, 1985. / Title from PDF t.p.
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Light scattering of semitransparent mediaLi, Qinghe. January 2008 (has links)
Thesis (M. S.)--Mechanical Engineering, Georgia Institute of Technology, 2008. / Committee Chair: Zhang, Zhuomin; Committee Member: Lee, Kok-Meng; Committee Member: Ready, W. Jud.
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Recombinant elastin-mimetic protein polymers as design elements for an arterial substituteSallach, Rory Elizabeth. January 2008 (has links)
Thesis (Ph.D)--Biomedical Engineering, Georgia Institute of Technology, 2008. / Committee Chair: Elliot Chaikof; Committee Member: Marc Levenston; Committee Member: Robert Nerem; Committee Member: Vincent Conticello; Committee Member: Yadong Wang. Part of the SMARTech Electronic Thesis and Dissertation Collection.
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Study of the plasma based production of tetrafluoroethyleneNell, Annalien 06 1900 (has links)
Thesis (MIng) --Stellenbosch University, 1999. / ENGLISH ABSTRACT: A method was developed at the Atomic Energy Corporation of South Africa (AEC) for the
plasma based production of tetrafluoroethylene (TFE). The process involves the feeding of
carbon particles into a direct-current CF4 plasma. The resultant plasma gas is quenched rapidly
to obtain TFE and other fluorocarbons. The mixing of the particles with the plasma gas is very
important in order to achieve a high C:F-ratio in the gas phase, which promotes the desired
reactions. The gas enthalpy in the reactor is a governing factor in the TFE yields that are
obtained.
In this study research was done on particle mixing and the enthalpy distribution in the laboratory
scale reactor. An enthalpy probe was used as the main diagnostic tool. Results indicated that
particle mixing is quite uniform throughout the reactor. A basic one-dimensional mechanistic
model of the reactor was also expanded to assist in· the scale-up of the process. In its present
form the model is adequate for predicting trends in the reactor. The model could still be
expanded further to include reaction kinetics and internal heat transfer in the particles.
Considering the restrictions of the model, satisfactory agreement was obtained between the
model and experimental results. / AFRIKAANSE OPSOMMING: 'n Proses vir die plasmagebaseerde produksie van tetrafluoroetileen (TFE) is deur die Atoomenergiekorporasie
van Suid-Afrika (AEK) ontwikkel. Koolstofpartikels word in 'n gelykstroomCF4-
plasma gevoer en die resulterende plasmagas word vinnig geblus ten einde TFE en ander
fluoor-koolstofverbindings as produkte te verkry. Goeie vermenging van die koolstofpartikels
met die plasmagas is van uiterste belang ten einde 'n hoe C:F-verhouding, wat die gewenste
reaksies bevorder, in die gasfase te verkry. Die entalpie van die plasmagas in die reaktor is 'n
bepalende faktor in die opbrengs TFE wat verkry word.
Vir die doel van hierdie werkstuk is navorsing op laboratoriumskaal gedoen oor partikelvermenging
en die entalpie-verspreiding in die reaktor. Die hoof diagnostiese apparaat wat vir
die doel aangewend is, is die entalpiesonde. Resultate toon dat partikelvermenging naastenby
uniform deur die reaktor voorkom. Verder is 'n basiese een-dimensionele meganistiese model
van die reaktor uitgebrei ten einde van nut te wees in die opskaling van die proses. In sy huidige
vorm is die model voldoende om algemene neigings in die reaktor te voorspel. Die model kan
nog verder uitgebrei word om reaksie-kinetika en interne hitte-oordrag in die partikels in te sluit.
Die beperkings van die model in ag genome, is ooreenstemming tussen die model en eksperimentele
resultate egter bevredigend.
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Numerical Analysis of Transient Teflon Ablation in Pulsed Plasma ThrustersStechmann, David Paul 16 July 2007 (has links)
"One of the general processes of interest in Pulsed Plasma Thrusters is the ablation of the solid fuel. In general, ablation occurs when a short pulse of applied energy removes a portion of the fuel surface. Although this ablation process is relatively straight-forward in simple materials that sublimate, ablation in Pulsed Plasma Thrusters is significantly more complicated. This is caused by the transient conditions and the complex behavior of Teflon that does not sublimate but rather undergoes both physical and chemical changes prior to leaving the surface. These two effects combine to make Teflon ablation a highly nonlinear function of heat flux, material property variations, changing molecular weight, and phase transformation behavior. To gain greater insight into the ablation process, a one-dimensional ablation model is developed that addresses the more detailed thermal and thermodynamic behavior of Teflon during simulated operation of a Pulsed Plasma Thruster. The mathematical model is based on the work of Clark (1971), which focused on two-phase, one-dimensional Teflon ablation in the context of thermal protection systems. The model is modified for use in simulated PPT operations and implemented numerically using an adaptive non-uniform grid, explicit finite-difference techniques, and a volume fraction method to capture the interface between the crystalline and amorphous Teflon phases. The ablation model is validated against analytical heat transfer and ablation solutions and compared with previous experimental results. The Teflon ablation model is used to analyze several general ablation scenarios in addition to specific PPT conditions to gain greater insight into long-duration thruster firing, post-pulse material ablation, variable heat flux effects, variable material property effects, and the impact of surface re-crystallization on particulate emission. These simulations are considered in the context of prior experimental investigations of Pulsed Plasma Thrusters. The results of these simulations demonstrate the success of the numerical ablation model in predicting experimental trend and suggest potential paths of moderately improving thruster efficiency and operational repeatability in the future. "
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Light scattering of semitransparent mediaLi, Qinghe 31 March 2008 (has links)
Polytetrafluoroethylene (PTFE) is a highly scattering material and has been used as diffuse reflectors. In the present study, the ranges of the scattering coefficient, absorption coefficient, and the asymmetric parameter of the Henyey-Greenstein scattering phase function are assessed for semitransparent PTFE films whose thicknesses range from 0.11 mm to 10 mm. The bidirectional reflectance distribution function (BRDF) and bidirectional transmittance distribution function (BTDF) of these PTFE films were measured using a laser scatterometer at a wavelength of 635 nm, and the directional-hemispherical reflectance and transmittance were obtained by integrating BRDF and BTDF at normal incidence. The scattering coefficient of PTFE is estimated to exceed 1200 (1/cm). On the other hand, the absorption coefficient should be less than 0.01 (1/cm). A Monte Carlo simulation was employed to predict the BRDF and BTDF of PTFE films, and the calculations were compared with measurements at various incidence angles.
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Equation of state for polytetrafluoroethylene (PTFE) and mixtures with PTFEWu, Zhibo 14 May 2009 (has links)
The objectives of this work are to discuss multiscale models that are used to characterize the constitutive relations of the granular composite materials with dual functions. This is accomplished by the use of ab initio methods to obtain the constitutive relations of the structural energetic materials without conducting tests. First, it is necessary to study the quantum many body problem to quantitatively determine the internal energy of the material when subjected to different strain conditions. It is impossible to obtain an exact solution to the quantum many body problem that is modeled by the Schrödinger's equations with the current technology. It is possible to solve these equations approximately by the density functional theory which yields only energies at absolute 0ºK. Thus it becomes necessary to add both the lattice thermal contributions and electron thermal contribution. Then, resulting energy is used to bridge to the continuum level and obtain the constitutive equations. This is the procedure that is used in this work.
The issues of the constitutive equations form the focus of this thesis. More specifically, the scope of the thesis is further restricted to analyze the constitutive equations of specific mixtures of nickel, aluminum with PTFE or Teflon as the binder. It is to be noted that the equations of state forms only a part of the complete constitutive relationships. This thesis presents solutions to the following problems:
(1) Determination of the thermodynamically complete equation of state of the binder and the energetic material PTFE or Teflon, from ab initio methods based on the density functional theory.
(2) Determination of the equations of state of the granular composite or the mixture of nickel, aluminum and PTFE from ab initio methods.
(3) Determination of the complete constitutive equation of aluminum, from ab initio methods, under conditions of finite deformations, with principle of objectivity, material symmetry conditions and polyconvexity of the strain energy.
All results are compared to test results whenever they are available.
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Mechanisms of liquid crystal and biopolymer alignment on highly-oriented polymer thin films /Dennis, John Raymond. January 1998 (has links)
Thesis (Ph. D.)--University of Washington, 1998. / Vita. Includes bibliographical references (leaves [89]-102).
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Recombinant elastin-mimetic protein polymers as design elements for an arterial substituteSallach, Rory Elizabeth 19 May 2008 (has links)
Recombinant synthesis of elastin-mimetic proteins has been employed for several decades, however, long-term biocompatibility and biostability of such proteins was not fully defined. We present virtually crosslinked elastin-mimetic proteins which exhibit exceptional biocompatibility and long-term biostability over a period of at least seven months. This report is the first evidence of a non-chemically or ionically crosslinked system that exhibits long-term in vivo stability.
Although, physically crosslinked protein-based materials possess a number of advantages over their chemically crosslinked counterparts, physical crosslinks and the related domains so formed may be deformed or damaged at applied stresses lower than those required to disrupt covalent crosslinks. In this regard, we have synthesized a new class of recombinant elastin-mimetic triblock copolymer capable of both physical and chemical crosslinking. We have demonstrated that chemical crosslinking provides an independent mechanism for control of protein mechanical responses. Specifically, elastic modulus was enhanced and creep strain reduced through the addition of chemical crosslinking sites.
A number of reports have described the design of synthetic genes, which encode elastin-like proteins for bacterial expression in Escherichia coli. Although advantages with this expression system exist, significant limitations including the lack of eukaryotic post-translational systems, the tendency to sequester mammalian proteins into inclusion bodies, difficult purification protocols, and endotoxin contamination have been noted. We demonstrate the expression of a recombinant elastin-mimetic protein from P. pastoris. A novel synthetic strategy, monomer library concatamerization, was utilized in designing non-repetitive elastin genes for highly repetitive protein sequences. It is likely that this strategy will be useful for creating large, repetitive genes for a variety of expression systems in order to more closely approach the genetic diversity inherent to native DNA sequences.
All told, elastin-based protein polymers are a promising class of material characterized by high degree of biocompatibility, excellent biostability, and a tunable range of mechanical properties from plastic to elastic. A variety of options facilitate the processing of these biopolymers into chemically crosslinked or non-crosslinked gels, films, or nanofibers for any of a number of implant applications including structural components of artificial organs and engineered living tissues, carriers for controlled drug release, or biocompatible surface coatings.
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