Global ETD Search

11	Psychosocial Characteristics of Youth Who Run Away From Home Al-Rawashdeh, Ahmad Bahjat 19 April 2006 (has links) No description available. Runaway Youth Sexual Abuse
12	The causes and consequenses [sic] of running away what difference does gender make? / Stinton, Amy Caroline. January 2007 (has links) Thesis (Ph. D. in Sociology)--Vanderbilt University, May 2007. / Title from title screen. Includes bibliographical references.
13	An interpretive study of the health experiences of runaway and homeless girls Taylor, Margaret A. Paulsen, January 2001 (has links) Thesis (Ph. D.)--University of Texas at Austin, 2001. / Vita. Includes bibliographical references. Available also from UMI/Dissertation Abstracts International.
14	An interpretive study of the health experiences of runaway and homeless girls / Taylor, Margaret A. Paulsen, January 2001 (has links) Thesis (Ph. D.)--University of Texas at Austin, 2001. / Vita. Includes bibliographical references (leaves 184-206). Available also in a digital version from Dissertation Abstracts.
15	A structured multiple baseline case study on runaway teenage girls / Li, Man-yi. January 1987 (has links) Thesis (M.S.W.)--University of Hong Kong, 1987.
16	Education in the streets : an ethnographic study of homeless youth in New York City / Hancock, Peter Mark. January 1988 (has links) Thesis (Ed.D.)--Teachers College, Columbia University, 1988. / Typescript; issued also on microfilm. Sponsor: Herve Varenne. Dissertation Committee: Paul Byers. Bibliography: leaves 112-115.
17	Experimental and Theoretical Study of Microwave Heating of Thermal Runaway Materials Wu, Xiaofeng 30 December 2002 (has links) There is growing interest in the use of microwaves to process materials. The main application of microwave processing of materials is in heating. The most important characteristic of microwave heating is {\it volumetric} heating, which is quite different from conventional heating where the heat must diffuse in from the surface of the material. Volumetric heating means that materials can absorb microwave energy directly and internally and convert it to heat. It is this characteristic that leads to advantages such as rapid, controlled, selective, and uniform heating. However, some problems hinder the widespread use of microwave energy. One of these problems is called thermal runaway, which is a type of thermal instability due to the interaction between the electromagnetic waves and materials. As thermal runaway occurs, the temperature of the heated material rises uncontrollably. The normal consequence of thermal runaway is the damage of the processed materials. The origins of thermal runaway are different under different processing conditions. When processing ceramic materials, thermal runaway is mainly due to the positive temperature dependence of dielectric loss of the material. These materials absorb more microwave energy as they are being heated. The most plausible explanation of this phenomenon is the so-called "S-curve" theory. However, prior to this work, no direct experimental evidence has been published to verify this theory. In this dissertation, we report the direct experimental evidence of the so-called "S-curve" by heating thermal runaway materials in a microwave resonant cavity applicator. A complete discussion of how the experimental results were achieved is presented. From the experimental results, we find that by the use of the cavity effects thermal runaway can be controlled. To explain the experimental findings, a theoretical model based on equivalent circuit theory is developed. Also, a coupled heat transfer and electromagnetic field model is developed to simulate the heating process. Both models give reasonably good comparison with our experimental results. Finally, a method to control thermal runaway is described. / Ph. D. Microwave processing materials Thermal runaway Thermal runaway control
18	Calorimetry of 'red-oil reactions' Glossop, Michael William January 1999 (has links) No description available. 660 Runaway reactions; Nuclear reprocessing
19	An Assessment on the Impact of Family Dynamics on the Runaway Problem Among Teenagers Ekici, Siddik 08 1900 (has links) Although Turkey is a country with strong social cohesion, figures of runaway children in Turkey are increasing dramatically. This research focused on the factors that cause children to run away and on interaction programs to intervene and/or prevent this problem. Until recently, Turkish family life was able to avoid such problems, but with the effect of westernization and social mobility in Turkey, the basic family structure has become more like the family structure in the western countries. Studies reveal that runaway episodes happen in all families regardless of such factors as economic, race, or geographic situations. Teenagers run away for several reasons; however, early intervention is highly suggested by studies to mitigate the problem. Although, parent-child conflict plays a significant role as a reason for youth leaving home, on the other hand family interaction still remains the best alternative to the problem. Family -- Turkey. runaway family dynamics teenager solutions runaway problem recommendations
20	Computational modeling of triple layered microwave heat exchanger Mohekar, Ajit 24 April 2018 (has links) A microwave heat exchanger (MHE) is a device which converts microwave (MW) energy into usable form of heat energy. The working principle of the MHE is based on a collective effect of electromagnetic wave propagation, heat transfer and fluid flow, so the development of an efficient device requires complicated experimentation with processes of different physical nature. A peculiar phenomenon making the design of MHE even more challenging is extit{thermal runaway}, a nonlinear phenomenon in which a small increase in the input power gives rise to a large increase in temperature. Such high temperature may result in material damage through excessive thermal expansion, cracking, or melting. In this Thesis, we report on an initial phase in the development of a computational model which may help clarify complicated interaction between nonlinear phenomena that might be difficult to comprehend and control experimentally. We present a 2D multiphysics model mimicking operation of a layered MHE that simulates the nonlinear interaction between MW, thermal, and fluid flow phenomena involved in the operation of the MHE. The model is built for a triple layered (fluid-ceramic-fluid) MHE and is capable of capturing the S- and SS-profiles of power response curve which determines steady-state temperature solution as a function of incident power. The model is implemented on the platform of the COMSOL Multiphysics modeling software. We show that a MHE with particular thickness and dielectric properties of the layers can operate efficiently by keeping temperatures during thermal runaway under control. Overall temperatures increase rapidly as soon as the local maximum temperature reaches a critical value. This condition is held true both in absence and in presence of fluid flow. It is demonstrated that the efficiency of the MHE dramatically increases when thermal runaway is achieved. As the amount of heat energy, which is being transferred to the fluid from the heated dielectric, increases, incident power required to achieve thermal runaway also increases. It is also shown that, with appropriate length of the layered MHE, thermal runaway can be achieved at a lower power level. While the model developed in this Thesis studies the basic operation of a three layered MHE, it can further be developed to investigate optimum design parameters of the MHE of other structures so that maximum thermal efficiency is achieved. thermal runaway microwave heat exchanger Computational modeling

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