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Growth and Swimming Endurance of Juvenile Channel Catfish in High Temperature EnvironmentsArnold, Michael B 12 May 2012 (has links)
Channel catfish (Ictalurus punctatus) are important to aquaculture and natural ecosystems, however little is known regarding effects of high summer temperatures, which are predicted to increase with climate change. Therefore, two studies were conducted to examine physiological effects of high temperatures on juvenile channel catfish. The first examined effects of three cycling thermal regimes (23-27°C, 27-31°C, and 31-35°C) characteristic of culture environments in Mississippi on growth, food consumption, feed conversion ratio, specific growth rate, and activity. The second study measured active and resting metabolic rates and swimming endurance at constant temperatures (27, 31, and 35°C). The best growth and feed conversion occurred at 27-31°C and activity was greatest at 31-35°C. Active metabolism and swimming endurance decreased at 35°C. These results indicate high summer temperatures reduce food consumption, increase activity, impair metabolism and endurance, and therefore present challenges to the culture and management of channel catfish.
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The effect of the aircrew chemical defence assembly on thermal strainThornton, Robert January 1988 (has links)
No description available.
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Investigation of the fracture behaviour of epoxy-based water ballastWu, Tongyu January 2015 (has links)
The fracture of water ballast tank (WBT) coatings due to thermal stresses is widely recognised as an issue. Upon coating fracture, rapid corrosion of the tanker steel structure will occur, leading to expensive structure repairs or even tanker scrapping. In this project, the fracture behaviour of two experimental WBT coatings, referred to as A and B, in the forms of free film and substrated coatings was investigated. Static tensile tests and fatigue tests of the substrated coatings were performed. A finite element model of coating cracking was developed. Thermal stress and J-integral of surface cracking defects in substrated coatings were calculated using the model, in which the effects of defect size, coating thickness, and thermal strain on coating fracture were investigated. For the first time, fracture mechanics was used to explain WBT coating fracture behaviour. The J-integral of surface defects was used to predict the onset strain of coating cracking under mechanical strains in laboratory and under thermal strains in service. A theoretical comparison between the cracking drive forces in terms of J - integrals in WBT coatings under thermal strains and mechanical strains was performed.
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A study of thermal environment in hotel kitchensMcDonnell, K. E. January 1988 (has links)
No description available.
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Numerical Analysis of Temperature and Thermal Stress in Cr4+:YAG fiber manufacturing processLai, Sheng-shin 18 August 2009 (has links)
Factors in fiber manufacturing procedures affect fiber¡¦s production, and the fiber quality will be affected accordingly. The residual stresses, in particular, have a significant influence on fiber quality, due to the mechanical strength and the refraction rate that has been changed. Mechanically, residual stresses may cause ruptures in the preform, reducing the intrinsic strength of the fiber and its durability; optically, it may also cause anisotropic distortions of the refractive index profiles.
In the process of cooling under high temperature, fiber core and cladding will be compressed owing to the material difference and the residual stress will be in the fiber. Thermal conductance and thermal expansion coefficient contribute to the cracks on the interface and thus affect the refraction rate. Experiments have shown that quartz and Cr4+¡GYAG will rupture on the interface as a result of the huge thermal expansion coefficient. According to researches, stress in different directions will bring about fiber cracks or changes of the refraction rate.
This paper mainly investigates the influence of material properties on the temperature field and thermal stress distribution in the cooling process of fiber and preform manufacturing by numerical simulations. The results show the preform temperature profile and the stress distribution in different directions. Also, through the stress distribution, the stress is known to be centered on the interface between core and cladding.
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Modelling the influence of manufacturing parameters on variation of residual stresses in quenched partsSedighi, Mohammad January 1998 (has links)
No description available.
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Development of a simplified thermal analysis procedure for insulating glass unitsKlam, Jeremy Wayne 02 June 2009 (has links)
A percentage of insulating glass (IG) units break each year due to thermally induced perimeter
stresses. The glass industry has known about this problem for many years and
an ASTM standard has recently been developed for the design of monolithic glass plates
for thermal stresses induced by solar irradiance. It is believed that a similar standard can
be developed for IG units if a proper understanding of IG thermal stresses can be developed.
The objective of this research is to improve understandings of IG thermal stresses
and compare the IG thermal stresses with those that develop in monolithic glass plates
given similar environmental conditions.
The major difference between the analysis of a monolithic glass plate and an IG unit is
energy exchange due to conduction, natural convection, and long wave radiation through
the gas space cavity. In IG units, conduction, natural convection, and long wave radiation
combine in a nonlinear fashion that frequently requires iterative numerical analyses
for determining thermal stresses in certain situations. To simplify the gas space energy
exchange, a numerical propagation procedure was developed. The numerical propagation
procedure combines the nonlinear effects of conduction, natural convection, and
long wave radiation into a single value. Use of this single value closely approximates the
nonlinear nature of the gas space energy exchange and simplifies the numerical analysis.
The numerical propagation procedure was then coupled with finite element analysis to
estimate thermal stresses for both monolithic glass plates and IG units. It is shown that the maximum thermal stresses that develop in IG units increase linearly with input solar
irradiance during the transient phase. It is shown that an initial preload stress develops
under equilibrium conditions due to the thermal bridge effects of the spacer. It is shown
that IG units develop larger thermal stresses than monolithic glass plates under similar
environmental conditions. Finally, it is shown that the use of low-e coatings increase IG
thermal stresses and that the location of low-e coating as well as environmental conditions
affect which glass plate develops larger thermal stresses.
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Numerical Analysis of Temperature and Thermal Stress of Chromium Doped Crystal Fiber SplicerLu, Jhu-You 03 August 2006 (has links)
The connection between the devices of optical fiber system is an important part of optical communication equipment. For reducing the power loss in single transfer process, we couple the light from one device to another by connecting with splicer and connector.
In the optical fiber communication system, the fiber must be coupled with light source or detectors and optical amplifier. The way connect fiber by fusion splice is different from the mechanical connectors, which is small joint volume, higher mechanical strength and much stable after connecting. It is more suitable to apply on micro-package optical communication device. In the study, we confer with the temperature profile and thermal stress of fusion splice module during splicing Cr4+¡GYAG crystal fiber and single mode fiber by numerical simulations. Through adjusting the parameters, like fusion current, fusion place and the processes of splice to examine the trend of change of temperature and thermal stress.
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Warpage Study of TFBGA PackagingWang, Chih-Hao 20 June 2001 (has links)
The current packaging trend toward to smaller and thinner has pushed the manufacturing technology to the limits. During the assembly processes of IC packages, delamination at interfaces and mechanical breakage of components are common mode of failure. The induced thermal stress within the package is one of the major contributions to these failures. According to the disparity of the coefficient of thermal expansion (CTE) between different components, internal thermal stress and warpage will be induced when the package undergoes temperature excursion. In this paper, the Die attach epoxy curing and encapsulation curing process induced warpage and thermal stress were studied by finite element software Marc & Mentat. As comparison, two kinds of Molding materials of the package considered, and the result will compared with the experimental data. Finally, studied the effect of the material thickness and the impact significance of each design variable on the design objective will also be discussed.
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Evaluation of thermal stresses in planar solid oxide fuel cells as a function of thermo-mechanical properties of component materialsManisha, 10 October 2008 (has links)
Fuel cells are the direct energy conversion devices which convert the chemical energy of a
fuel to electrical energy with much greater efficiency than conventional devices. Solid Oxide
Fuel Cell (SOFC) is one of the various types of available fuel cells; wherein the major
components are made of inherently brittle ceramics. Planar SOFC have the advantages of
high power density and design flexibility over its counterpart tubular configuration.
However, structural integrity, mechanical reliability, and durability are of great concern for
commercial applications of these cells. The stress distribution in a cell is a function of
geometry of fuel cell, temperature distribution, external mechanical loading and a mismatch
of thermo-mechanical properties of the materials in contact. The mismatch of coefficient of
thermal expansion and elastic moduli of the materials in direct contact results in the
evolution of thermal stresses in the positive electrode/electrolyte/negative electrode (PEN)
assembly during manufacturing and operating conditions (repeated start up and shut down
steps) as well. It has long been realized and demonstrated that the durability and reliability of
SOFCs is not only determined by the degradation in electrochemical performance but also
by the ability of its component materials to withstand the thermal stresses.
In the present work, an attempt has been made to evaluate the thermal stresses as a function
of thermal and mechanical properties of the component materials assuming contribution
from other factors such as thermal gradient, mechanical loading and in-service loading
conditions is insignificant. Materials used in the present study include the state of art anode (Ni-YSZ), electrolyte(YSZ) and cathode materials(LM and LSM) of high temperature SOFC
and also the ones being suggested for intermediate temperature SOFC Ni-SCZ as an anode,
GDC and SCZ as electrolyte and LSCF as the cathode. Variation of thermo-mechanical
properties namely coefficient of thermal expansion, and elastic and shear moduli were
studied using thermo-mechanical analyzer and resonant ultrasound spectroscope respectively
in 25-900°C temperature range. A non-linear variation in elastic and shear moduli- indicative
of the structural changes in the studied temperature range was observed for most of the
above mentioned materials. Coefficient of thermal expansion (CTE) was also found to
increase non-linearly with temperature and sensitive to the phase transformations occurring
in the materials. Above a certain temperature (high temperature region- above 600°C), a
significant contribution from chemical expansion of the materials was also observed.
In order to determine thermal stress distribution in the positive electrode, electrolyte,
negative electrode (PEN) assembly, CTE and elastic and shear moduli of the component
materials were incorporated in finite element analysis at temperature of concern. For the
finite element analysis, anode supported configuration of PEN assembly (of 100mm x
100mm) was considered with 1mm thick anode, 10μm electrolyte and 30μm cathode. The
results have indicated that cathode and anode layer adjacent to cathode/electrolyte and
electrolyte/anode interface respectively are subjected to tensile stresses at the operating
temperature of HT-SOFC (900°C) and IT-SOFC (600°C). However, the magnitude of
stresses is much higher in the former case (500MPa tensile stress in cathode layer) when
compared with the stress level in IT-SOFC (178MPa tensile stress in cathode layer). These
high stresses might have been resulted from the higher CTE of cathode when compared with
the adjacent electrolyte. However, it is worth mentioning here that in the present work, we
have not considered any contribution from the residual stresses arising from fabrication and
the stress relaxation from softening of the glass sealant.
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