Dynamic modeling and vibration analysis of mistuned bladed disks

Óttarsson, Gísli

19 May 1994

One of the most important problems that plague turbomachinery rotors is the existence of rogue blades -- lone blades that exhibit unexpected fatigue failure. It has been recognized that rotor mistuning might be the cause of rogue blades through a phenomenoncalled normal mode localization, whereby vibration energy is confined to a few blades of the assembly. The goals of this dissertation are (1) to achieve a thorough understanding of the fundamental mechanisms governing mistuning effects, (2) the development of mathematical models of turbomachinery rotors suitable for mistuning analysis, and (3) the development of techniques for designers interested in the mistuning sensitivity of a particular rotor design.

mistuning

bladed-disk assemblies

localization

lumped models

Understanding, Modeling and Predicting Hidden Solder Joint Shape Using Active Thermography

Giron Palomares, Jose

2012 May 1900

Characterizing hidden solder joint shapes is essential for electronics reliability. Active thermography is a methodology to identify hidden defects inside an object by means of surface abnormal thermal response after applying a heat flux. This research focused on understanding, modeling, and predicting hidden solder joint shapes. An experimental model based on active thermography was used to understand how the solder joint shapes affect the surface thermal response (grand average cooling rate or GACR) of electronic multi cover PCB assemblies. Next, a numerical model simulated the active thermography technique, investigated technique limitations and extended technique applicability to characterize hidden solder joint shapes. Finally, a prediction model determined the optimum active thermography conditions to achieve an adequate hidden solder joint shape characterization. The experimental model determined that solder joint shape plays a higher role for visible than for hidden solder joints in the GACR; however, a MANOVA analysis proved that hidden solder joint shapes are significantly different when describe by the GACR. An artificial neural networks classifier proved that the distances between experimental solder joint shapes GACR must be larger than 0.12 to achieve 85% of accuracy classifying. The numerical model achieved minimum agreements of 95.27% and 86.64%, with the experimental temperatures and GACRs at the center of the PCB assembly top cover, respectively. The parametric analysis proved that solder joint shape discriminability is directly proportional to heat flux, but inversely proportional to covers number and heating time. In addition, the parametric analysis determined that active thermography is limited to five covers to discriminate among hidden solder joint shapes. A prediction model was developed based on the parametric numerical data to determine the appropriate amount of energy to discriminate among solder joint shapes for up to five covers. The degree of agreement between the prediction model and the experimental model was determined to be within a 90.6% for one and two covers. The prediction model is limited to only three solder joints, but these research principles can be applied to generate more realistic prediction models for large scale electronic assemblies like ball grid array assemblies having as much as 600 solder joints.

active thermography

hidden solder joint

FEA

multi PCB assemblies

nondestructive evaluation

parametric analysis

artificial neural networks

Hygrothermal Performance of Insulated, Sloped, Wood-Framed Roof Assemblies

Schumacher, Christopher James

January 2008

Roofs are the single enclosure element common to artificial shelters constructed by all cultures in all climate regions. The hygrothermal performance of insulated, sloped, wood-framed roof assemblies has long been of interest to building scientists and building codes alike. Requirements for the ventilation of roof assemblies have been included in building codes for more than 50 years, however moisture problems still occur. Unvented roof assemblies have been suggested as an alternate and potentially superior solution. While unvented roofs have become relatively common in the warmer southern climates of North America, some technical issues remain unclear and the need exists for further study and demonstration of the hygrothermal performance of both ventilated and unvented roof assemblies in cold northern climates. This thesis seeks to address these issues through a review of existing literature, experience and industry practice, field investigation and measurement, analytical calculation and computer simulations.

roof assemblies

hygrothermal performance

unvented roofs

ventilated attics

sloped roofs

wood-framed roofs

Civil Engineering

Hygrothermal Performance of Insulated, Sloped, Wood-Framed Roof Assemblies

Schumacher, Christopher James

January 2008

Roofs are the single enclosure element common to artificial shelters constructed by all cultures in all climate regions. The hygrothermal performance of insulated, sloped, wood-framed roof assemblies has long been of interest to building scientists and building codes alike. Requirements for the ventilation of roof assemblies have been included in building codes for more than 50 years, however moisture problems still occur. Unvented roof assemblies have been suggested as an alternate and potentially superior solution. While unvented roofs have become relatively common in the warmer southern climates of North America, some technical issues remain unclear and the need exists for further study and demonstration of the hygrothermal performance of both ventilated and unvented roof assemblies in cold northern climates. This thesis seeks to address these issues through a review of existing literature, experience and industry practice, field investigation and measurement, analytical calculation and computer simulations.

roof assemblies

hygrothermal performance

unvented roofs

ventilated attics

sloped roofs

wood-framed roofs

Civil Engineering

"Choosing the Jesus Way:" the Assemblies of God's Home Missions to American Indians and the Development of an Indian Pentecostal Identity

Tarango, Angela

January 2009

<p>This dissertation explores the history of the Assemblies of God's Home Missions to American Indians, the development of an American Indian leadership in the denomination and the development of a Pentecostal Indian identity. The history that is told in this work is that of a century-long struggle by American Indian Pentecostals for autonomy, leadership, and recognition within the Assemblies of God. I argue that the AG's efforts to establish indigenous churches in its home missions work to American Indians bore two important and largely unanticipated consequences. The first was that it prompted American Indian Pentecostals to forge a new identity: fully Indian and fully Pentecostal. The second was that it forced white Pentecostals to own up to their belief in the indigenous principle: that God's Spirit fell equally on peoples, without regard to ethnicity or social standing. I focus mainly on giving voice to the Pentecostal Indian actors in this history, in order to fill in the gaps on a group of modern Pentecostal believers that were almost never written about in the histories of the movement.</p><p> I have rooted this work in the history of American religious history, as well as Native American history and the history of American Pentecostalism. The majority of the sources come from the Assemblies of God's archives, chiefly, ministerial files, Pentecostal periodicals, letters, tracts, meeting minutes, and self-published autobiographies.</p> / Dissertation

Religion, History of

Native American Studies

Assemblies of God

Missions

Native Americans

Pentecostalism

Synergistic photon absorption enhancement in nanostructured molecular assemblies

Gao, Ting-fong

30 July 2012

Molecular photoabsorption enhancement under ambient solar radiations can improve efficiency substantially in renewable energy production. Here, we explore the theoretical basis and experimental evidences that nanostructured molecular assemblies exhibit an unprecedented property of synergistic photon absorption enhancement. The molecular mechanism of this enhancement phenomenon originates from the combined effect of the photon-molecule interaction and the electronic energy transfer between two adjacent molecular assemblies. For a natural system, the synergistic photon absorption enhancement factor of green algae (Chlorella vulgaris) in vivo at 632.8 nm was determined to be 103. This enhanced photon absorption process in nanostructured molecular assemblies opens a doorway to create entangled double excitons by incoherent solar radiations.

electronic energy transfer

molecular assemblies

double exciton

nanostructure

renewable energy

quantum entanglement

Thermal-Hydraulic Analysis of Advanced Mixed-Oxide Fuel Assemblies with VIPRE-01

Bingham, Adam R.

2009 May 1900

Two new fuel assembly designs for light water reactors using advanced mixed-oxide fuels have been proposed to reduce the radiotoxicity of used nuclear fuel discharged from nuclear power plants. The research efforts of this thesis are the first to consider the effects of burnup on advanced mixed-oxide fuel assembly performance and thermal safety margin over an assembly?s expected operational burnup lifetime. In order to accomplish this, a new burnup-dependent thermal-hydraulic analysis methodology has been developed. The new methodology models many of the effects of burnup on an assembly design by including burnup-dependent variations in fuel pin relative power from neutronic calculations, assembly power reductions due to fissile content depletion and core reshuffling, and fuel material thermal-physical properties. Additionally, a text-based coupling method is developed to facilitate the exchange of information between the neutronic code DRAGON and thermal-hydraulic code VIPRE-01. The new methodology effectively covers the entire assembly burnup lifetime and evaluates the thermal-hydraulic performance against ANS Condition I, II, and III events with respect to the minimum departure from nucleate boiling ratio, peak cladding temperatures, and fuel centerline temperatures. A comprehensive literature survey on the thermal conductivity of posed fuel materials with burnup-dependence has been carried out to model the advanced materials in the thermal-hydraulic code VIPRE-01. Where documented conductivity values are not available, a simplified method for estimating the thermal conductivity has been developed. The new thermal conductivity models are based on established FRAPCON-3 fuel property models used in the nuclear industry, with small adjustments having been made to account for actinide additions. Steady-state and transient thermal-hydraulic analyses are performed with VIPRE- 01 for a reference UO2 assembly design, and two advanced mixed-oxide fuel assembly designs using the new burnup-dependent thermal-hydraulic analysis methodology. All three designs maintain a sufficiently large thermal margin with respect to the minimum departure from nucleate boiling ratio, and maximum cladding and fuel temperatures during partial and complete loss-of-flow accident scenarios. The presence of a thin (Am,Zr)O2 outer layer on the fuel pellet in the two advanced mixed-oxide fuel assembly designs increases maximum fuel temperatures during transient conditions, but does not otherwise greatly compromise the thermal margin of the new designs.

Thermal-hydraulic

fuel assembly

fuel assemblies

mixed-oxide

VIPRE

VIPRE-01

Employing double-stranded DNA probes on colloidal substrates for competitive hybridization events

Baker, Bryan Alexander

01 April 2010

The study of the DNA has found application beyond our understanding of its cellular function and into a variety of materials assembly and nucleic acid detection systems. The current research investigates double-stranded DNA probes in both a colloidal particle assembly and fluorescent assay format utilizing competitive hybridization events. In both contexts, the affinity of the dsProbes is tuned by the sequence design parameters of duplex length and complementarity. These systems were incubated with nucleic acid targets of interest and, based on the mechanism of competitive hybridization, were responsive to the presence of a high affinity competitive target. In the case of the particle assemblies, incubation with the competitive target resulted in observable disassembly of particle structures. In the case of fluorescently labeled dsProbes, incubation with competitive targets resulted in a quantifiable loss of fluorescence as determined by flow cytometry. Utilizing the fluorescently labeled dsProbe system, the kinetics of competitive hybridization was characterized for nucleic acid targets of varying specificity and strand context. The results indicate promise for the development of the competitive hybridization approach in nucleic acid detection systems providing advantages over current single-stranded probe designs. By utilizing a fluorescently labeled dsProbe approach, it is unnecessary to chemically modify the target of interest to impart a signaling mechanism. Additionally, as the process of competitive hybridization of dsProbes with targets of interest is an affinity driven process, discrimination of targets based on specificity is decoupled from standard measures such as elevated temperature protocols, an important step in translating nucleic acid technologies from the controlled laboratory environment to field applications.

Double-stranded probes

Competitive hybridization

DNA

Particle assemblies

Colloids

DNA probes

Self-assembly (Chemistry)

The establishment of a ministry training school in Kamloops, British Columbia

Beck, Jeffrey R.

January 2002

Thesis (D. Min.)--Trinity International University, 2002. / Abstract. Includes bibliographical references (leaves 224-227).

The church community's impact on help seeking of battered Christian women /

Watson, Jo-Ellen.

January 2002

Thesis (Ph. D.)--University of Washington, 2002. / Vita. Includes bibliographical references (leaves 173-183).