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Development Of Mirror Flexures For Use In The Muvi InstrumentHarrop, Colin W 01 April 2023 (has links) (PDF)
The Miniaturized Ultraviolet Imager (MUVI), is a compact wide field UV imaging instrument in development at UC Berkeley Space Sciences Laboratory and Cal Poly, San Luis Obispo. MUVI is designed to fit in a 2U CubeSat form factor and provide wide field, high resolution images of the ionosphere at far ultraviolet wavelengths. This thesis details the design and analyses of MUVI’s deployable cover mirror mounting flexures. Three different flexure geometries were evaluated, an optimal candidate was determined based on a number of criteria including isolation of vibration and stress to the mirrors, manufacturability and cost. The design of the flexure system includes the flexure blades themselves, Invar pads bonded to the mirror to mitigate the difference in CTEs of the different material, mounting of flexure blades to the deployable cover and ground support equipment for assembly and testing.
During the design of the flexures, various materials were studied, and Titanium was concluded as the optimum material due to its combination of high strength and flexibility compared to stainless steel, aluminum and other metals. Utilizing titanium, several flexure designs were proposed, and three candidates were selected to be manufactured and tested. Throughout the design phase, all flexures went through several rounds of analysis utilizing finite element analysis to simulate quasi-static loads, modal analysis of the systems natural frequency as well as random vibration simulations to simulate testing environments.
Once the front-runner designs were selected and manufactured, several tests were conducted. Testing included adhesive bond coupon testing of the adhesive in tension and bending to experimentally validate the bonding size of the invar pads would be sufficient. The adhesive bond testing conducted tension and three-point bend tests to characterize the epoxy adhesive used in the flexure assembly. Testing also consisted of sine sweep and random vibration environment in accordance with the NASA General Environmental Verification Standard to qualify the hardware for spaceflight. Throughout the vibration testing, an autocollimator was used pre and post-test to measure shifts in the optical alignment of the mirror after it underwent vibration qualification testing.
Experimental and analytical models were compared once all testing was completed. The Curved Blade showed to test in the real world very close to that predicted by the finite element model, however, the Bent Blade and Z Blade showed a larger difference between analysis and test. Discussion into the reasoning for this difference and lessons learned is included.
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Flexural behaviour of continuously supported FRP reinforced concrete beams.Habeeb, M.N. January 2011 (has links)
This thesis has investigated the application of CFRP and GFRP bars as longitudinal reinforcement for continuously supported concrete beams.
Two series of simply and continuously supported CFRP and GFRP reinforced concrete beams were tested in flexure. In addition, a continuously supported steel reinforced concrete beam was tested for comparison purposes. The FRP reinforced concrete continuous beams were reinforced in a way to accomplish three possible reinforcement combinations at the top and bottom layers of such continuous beams.
The experimental results revealed that over-reinforcing the bottom layer of either the simply or continuously supported FRP beams is a key factor in controlling the width and propagation of cracks, enhancing the load capacity, and reducing the deflection of such beams. However, continuous concrete beams reinforced with CFRP bars exhibited a remarkable wide crack over the middle support that significantly influenced their behaviour.
The ACI 440.1R-06 equations have been validated against experimental results of beams tested. Comparisons between experimental results and those obtained from
simplified methods proposed by the ACI 440 Committee show that ACI 440.1R-06 equations can reasonably predict the load capacity and deflection of the simply and continuously supported GFRP reinforced concrete beams tested. However, The potential capabilities of these equations for predicting the load capacity and deflection of continuous CFRP reinforced concrete beams have, however, been adversely affected by the de-bonding of top CFRP bars from concrete.
An analytical technique, which presents an iterative procedure based on satisfying force equilibrium and deformation compatibility conditions, has been introduced in this research. This technique developed a computer program to investigate flexural behaviour in particular the flexural strength and deflection of simple and continuously supported FRP reinforced concrete beams.
The analytical modelling program has been compared against different prediction methods, namely ACI 440, the bilinear method, mean moment inertia method and Benmokrane¿s method. This comparison revealed the reliability of this programme in producing more enhanced results in predicting the behaviour of the FRP reinforced beams more than the above stated methods.
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Flexural behavior of a glass fiber reinforced wood fiber compositeSmulski, Stephen John January 1985 (has links)
The static and dynamic flexural properties of a wood fiber matrix internally reinforced with continuous glass fibers were investigated. When modelled as a sandwich composite, the static flexural modulus of elasticity (MOE) of glass fiber reinforced hardboard could be successfully predicted from the static flexural MOE of the wood fiber matrix, and the tensile MOE and effective volume fraction of the glass fiber reinforcement. Under the same assumption, the composite modulus of rupture (MOR) is a function of the reinforcement tensile MOE and effective volume fraction, and the matrix stress at failure. The composite MOR was predicted on this basis with limited success.
The static flexural modulus of elasticity, dynamic modulus of elasticity, and modulus of rupture of glass fiber reinforced hardboard increased with increasing effective reinforcement volume fraction. The logarithmic decrement of the composite decreased with increasing effective reinforcement volume fraction. Excellent linear correlation found among flexural properties determined in destructive static tests and nondestructive dynamic tests demonstrated the usefulness of dynamic test methods for flexural property evaluation.
The short-term flexural creep behavior of glass fiber reinforced hardboard was accurately described by a 4-element linear viscoelastic model. Excellent agreement existed between predicted and observed creep deflections based on nonlinear regression estimates of model parameters. / Ph. D.
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Warm mix asphalt vs. hot mix asphalt : flexural stiffness and fatigue life evaluationVan den Heever, Johann 04 1900 (has links)
Thesis (MScEng)--Stellenbosch University, 2014. / ENGLISH ABSTRACT: The UNFCCC (United Nations Framework Convention on Climate Change), enabled
by the Kyoto Protocol, set enforced responsibilities on industrialised countries to
reduce the amount of emissions (greenhouse gases) produced. This global call for
the reduction of greenhouse gas emissions ensured that the manufacturing sector
commit to emission reduction.
The asphalt industry has embarked on a quest to find alternative methods of
producing and constructing asphalt mixes which will release less greenhouse gasses
into the atmosphere. These new methods include the reduction in production and
construction temperatures which in turn will reduce the amount of greenhouse
emissions produced. These new methods introduced the concept of warm mix
asphalt (WMA) to the alternative hot mix asphalt (HMA).
To produce a WMA mix at lower temperatures the binder needs to be in a workable
state so to effectively coat the aggregate and produce a good quality mix. WMA
technologies have been developed to enable production of mixes at lower
temperatures (effectively reducing emissions) whilst retaining the required binder
viscosity and properties needed to produce a quality mix. The question which needs
to be answered is whether the performance of these WMA mixes can compare with
that of HMA mixes.
In this study several WMA mixes (with different WMA technologies) are evaluated
against their equivalent HMA mixes in terms of fatigue life and flexural stiffness.
Phase angle results were also considered. Flexural stiffness is a mix property which
is dependent on loading time and temperature. It is used to measure the load spread
ability of a mix and also influences fatigue behaviour. Fatigue cracking occurs in the
material as a result of repeated cyclic loading. The evaluation and analysis conducted in this study show that WMA mixes can
compare favourably and even exceed that of HMA mixes in certain cases, although
some WMA mixes resulted in lower fatigue life or flexural stiffness than its
corresponding HMA mixes, which could be attributed to differences in mix
components and variables.
In this study a literature study, methodology, laboratory test results, a comparison of
mix results and conclusions and recommendations are made. / AFRIKAANSE OPSOMMING: Die UNFCCC (United Nations Framework Convention on Climate Change) was in
staat gestel deur die Kyoto Protocol om verantwoordelikhede op geïndustrialiseerde
lande te forseer om die hoeveelheid van nadelige kweekhuisgasse wat geproduseer
word te verminder. Hierdie globale oproep tot die vermindering van kweekhuisgasse
verseker dat die vervaardigingsektor hulself verbind tot emissie vermindering.
Die asfalt industrie het begin met 'n soektog na alternatiewe metodes van
vervaardiging en die bou van asfaltmengsels wat minder kweekhuisgasse sal vrystel
in die atmosfeer. Hierdie nuwe metodes sluit die vermindering in produksie en
konstruksie temperature in wat op sy beurt die hoeveelheid kweekhuisgasse
geproduseer verminder. Hierdie nuwe metodes het die konsep van warm mengsel
asfalt (WMA) bekendgestel teenoor die alternatiewe ‘hot’ mengsel asfalt (HMA).
Om ‘n WMA mengsel te produseer by laer temperature, moet die bindmiddel in 'n
werkbare toestand wees om die aggregaat heeltemal te bedek en 'n goeie gehalte
mengsel te produseer. WMA tegnologie is ontwikkel om die produksie van mengsels
teen laer temperature te realiseer (vermindering die uitlaatgasse), terwyl die vereiste
bindmiddel viskositeit en eienskappe wat nodig is om 'n kwaliteit mengsel te
produseer behou word. Die vraag wat beantwoord moet word, is of die prestasie van
hierdie WMA mengsel kan vergelyk word met dié van HMA mengsel.
In hierdie studie is 'n paar WMA mengsels (met verskillende WMA tegnologie)
geëvalueer teen hul ekwivalent HMA mengsels in terme van vermoeiing en buig
styfheid. Fase hoek resultate is ook in ag geneem. Buig styfheid is 'n mengsel
eienskap wat afhanklik is van die laai tyd en temperatuur. Dit word gebruik om die las
verspreiding vermoë van 'n mengsel te meet en beïnvloed ook vermoeiing gedrag.
Vermoeidheid krake kom voor in die materiaal as gevolg van herhaalde sikliese laai. Die evaluering en ontleding in hierdie studie toon dat WMA mengsels goed vergelyk
en selfs in sekere gevalle meer as dié van HMA mengsels, hoewel sommige WMA
mengsels laer vermoeidheid lewe of buig styfheid as die ooreenstemmende HMA
mengsels gewys het, wat toegeskryf kan word tot verskille in mengsel komponente
en veranderlikes.
In hierdie studie word 'n literatuurstudie, metodiek, laboratorium toets resultate, 'n
vergelyking van die mengsel resultate en gevolgtrekkings en aanbevelings gemaak.
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Contribuições teórico-experimentais para a definição das propriedades mecânicas do concreto com fibras aplicadas em simulações numéricas com foco na interação flexão-cisalhamento em vigas de concreto armado / Theoretical-experimental contributions for the definition of the mechanical properties of steel fiber reinforced concrete applied in numerical simulations focusing on the flexion-shear interaction in reinforced concrete beamsSilva, Matheus Fernandes de Araújo 28 January 2019 (has links)
A verificação ao cisalhamento de vigas de concreto armado é realizada, geralmente, assumindo sua independência do comportamento à flexão. Dentre os mecanismos que influenciam na resistência à força cortante, a força cortante transmitida pelo banzo comprimido da viga e o engrenamento de agregados são os mais abordados em pesquisas nos ultimos anos. Ambos dependem do nível de tensões normais atuante na seção do elemento. Sendo assim, o comportamento ao cisalhamento fica evidentemente dependente do comportamento à flexão e de como o concreto se comporta à tração e à compressão. Para melhor entender este comportamento, este trabalho compreendeu duas frentes de análise: experimental e numérica. Ensaios de tirantes foram realizados no intuito de avaliar o enrijecimento à tração do concreto com fibras. Além disso, ensaios de flexão em três pontos em prismas de 15cm x 15cm x 50 cm foram feitos para avaliar o comportamento pós-pico à tração do concreto. Ensaios de compressão em cilindros de concreto 10×20cm foram realizados de maneira a apontar estimativas para a energia de fratura à compressão e o comportamento pós-pico do concreto com diferentes taxas volumétricas de fibras. Seguindo os resultados experimentais, simulações numéricas dos ensaios de flexão em três pontos e dos ensaios de compressão foram desenvolvidas com o intuito de melhorar o entendimento dos ensaios realizados. Estes estudos aperfeiçoaram primordialmente os conhecimentos do comportamento do concreto à tração e compressão pós-fissuração. Foram ensaiadas nove vigas de concreto armado variando volume de fibras e a relação entre a distância da carga até o apoio mais próximo e a altura útil da viga ( a / d). Os resultados destes ensaios mostram que a resistência à força cortante aumenta com a taxa volumétrica de fibras e que o esquema estático adotado interfere pouco na resistência. Além disso, os resultados do estudo de caracterização do comportamento pós-pico do concreto foi aplicado na simulação numérica da viga. Os resultados numéricos apontam diferenças na rigidez global quando comparados com os resultados experimentais. / The shear strength verification of reinforced concrete beams is generally performed assuming their independence from the flexural behavior. Among the mechanisms that influence the shear strength, the shear force transmitted by the concrete compressed zone of the beam and the aggregate interlock are the most studied in the last years. Both depend on the level of normal stresses acting on the element section. Therefore, the shear behavior is obviously dependent on the flexural behavior and how the concrete behaves in tension and compression. For a better understanding, this work comprised two fronts of analysis: experimental and numerical. Tension ties tests were performed in order to evaluate the tension stiffening of concrete with fibers. In addition, three-point bending tests on 15cm x 15cm x 50cm prisms were made to evaluate the post-peak tension behavior of the concrete, or tension softening. Compression tests on 10 × 20cm concrete cylinders were carried out in order to estimate the compression fracture energy and the post-peak behavior of concrete with different volumetric fiber rates. Following the experimental results, numerical simulations of the three-point bending tests and the compression tests were developed with the aim of improving the understanding of the tests performed. These studies have the aim of improving the understanding of the three-point bending and compression tests performed. Nine reinforced concrete beams were tested, varying the volume of fibers and the relation between the distance of the load to the closest support and the useful height of the beam (a/d). The results of these tests show that shear strength increases with the volumetric rate of fibers and that the static scheme adopted does not interfere in resistance. In addition, the results of the post-peak concrete characterization study of the concrete were applied in the numerical simulation of the beam. Numerical results show differences in overall stiffness when compared with experimental results.
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System for measurement of cohesive lawsWalander, Tomas January 2009 (has links)
In this thesis an experimental method to calculate cohesive characteristics for an adhesive layer in a End Notched Flexure (ENF) specimen is presented and evaluated. The method is based on the path independent J-integral where the energy release rate (ERR) for the adhesive is derived as a function of the applied forces and the rotational displacements at the loading point and at the supports of the specimen. The major advantage with the method in comparison with existing theory known by the job initiator is that it is still applicable with ENF specimens that are subjected to yielding of the adherends. The structure of this thesis is disposed so that the theory behind the J-integral method is shortly described and then an evaluation of the method is performed by aid of finite element simulations using beam and cohesive elements. The finite element simulations indicates that the ERR can be determined with good accuracy for an ENF specimen where a small scale yielding of the adherends has occurred. However when a fully cross sectional yielding of the adherends is reached the ERR starts diverging from the exact value and generates a too high ERR according to input data in the simulations, i.e. the exact values. The importance in length of the adhesive process zone is also shown to be irrelevant to the ERR measured according to the J-integral method. Simulation performed with continuum elements indicates that a more reality based FE- simulation implies a higher value of the applied load in order to create crack propagation. This is an effect of that the specimen is allowed to roll on the supports which makes the effective length between the supports shorter than the initial value when the specimen is deformed. This results in a stiffer specimen and thus a higher applied force is needed to create crack propagation in the adhesive layer. An experimental set up of an ENF specimen is created and the sample data from the experiments are evaluated with the J-integral method. For measuring the rotational displacements of the specimen which are needed for the J-integral equation an image system is developed by the author and validated by use of linear elastic beam theory. The system calculates the three rotational displacements of the specimen by aid of images taken by a high resolution SLR camera and the system for measuring the rotations may also be used in other applications than for a specific ENF geometry. The validation of the image system shows that the rotations calculated by the image system diverge from beam theory with less than 2.2 % which is a quite good accuracy in comparison with the accuracies for the rest of the used surveying equipment. The results from the experiment indicates that the used, about 0.36 mm thick SikaPower 498, adhesive has an maximum shear strength of 37.3 MPa and a critical shear deformation of 482 µm. The fracture energy is for this thickness of the adhesive is determined as 12.9 kJ/m2. This report ends with a conclusion- and a suggested future work- chapter.
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Evaluation of an Interphase Element using Explicit Finite Element AnalysisSvensson, Daniel, Walander, Tomas January 2008 (has links)
A research group at University of Skövde has developed an interphase element for implementation in the commercial FE-software Abaqus. The element is using the Tvergaard & Hutchinson cohesive law and is implemented in Abaqus Explicit version 6.7 using the VUEL subroutine. This bachelor degree project is referring to evaluate the interphase element and also highlight problems with the element. The behavior of the interphase element is evaluated in mode I using Double Cantilever Beam (DCB)-specimens and in mode II using End Notch Flexure (ENF)-specimens. The results from the simulations are compared and validated to an analytical solution. FE-simulations performed with the interphase element show very good agreement with theory when using DCB- or ENF-specimens. The only exception is when an ENF-specimen has distorted elements. When using explicit finite element software the critical time step is of great importance for the results of the analyses. If a too long time step is used, the simulation will fail to complete or complete with errors. A feasible equation for predicting the critical time step for the interphase element has been developed by the research group and the reliability of this equation is evaluated. The result from simulations shows an excellent agreement with the equation when the interphase element governs the critical time step. However when the adherends governs the critical time step the equation gives a time step that is too large. A modification of this equation is suggested.
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Experimental Characterization of the Effect of Microstructure on the Dynamic Behavior of SiCMartin, Samuel R. 08 July 2004 (has links)
For roughly fifteen years the military has sought to use the properties of ceramics for armor applications. Current high-performance ceramics have extremely high compressive strengths and low densities. One ceramic that has been shown to be highly resistant under ballistic impact is silicon carbide (SiC). It has been found that even within the silicon carbides, those manufactured by certain methods and those with certain microstructural properties have advantages over others. In order to understand the microstructural reasons behind variations in ballistic properties, plate impact tests were conducted on two sintered silicon carbides with slightly different microstructures.
Two variations of a silicon carbide with the trade name Hexoloy SA were obtained through Saint Gobain. Regular Hexoloy (RH) and Enhanced Hexoloy (EH) are pressureless sintered products having exactly the same chemistries. EH went through additional powder processing prior to sintering, producing a final product with a slightly different morphology than RH. Samples of each were characterized microstructurally including morphology, density, elastic wavespeeds, microhardness, fracture toughness, and flexure strength. The characterization revealed differences in porosity distribution and flexure strength. It was determined that the porosity distribution in EH had fewer large pores leading to an 18% increase in flexural strength over that for RH.
The focus of the mechanics of materials community concerning dynamic material behavior is to pin down what exactly is happening microstructurally during ballistic events. Several studies have been conducted where material properties of one ceramic type are varied and the dynamic behavior is tested and analyzed. Usually, from one variation to the next, several properties are different making it hard to isolate the effect of each. For this study, the only difference in the materials was porosity distribution.
Plate impact experiments were conducted at the Army Research Laboratory (ARL) using the gas gun facilities within the Impact Physics Branch. A VISAR was utilized to measure free surface velocities. Tests were performed on each material to determine the Hugoniot Elastic Limit (HEL) and spall strength. Spall strength was measured as a function of impact stress, and pulse duration.
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Durability of Pulp Fiber-Cement CompositesMohr, Benjamin J. 19 July 2005 (has links)
Wood pulp fibers are a unique reinforcing material as they are non-hazardous, renewable, and readily available at relatively low cost compared to other commercially available fibers. Today, pulp fiber-cement composites can be found in products such as extruded non-pressure pipes and non-structural building materials, mainly thin-sheet products. Although natural fibers have been used historically to reinforce various building materials, little scientific effort has been devoted to the examination of natural fibers to reinforce engineering materials until recently. The need for this type of fundamental research has been emphasized by widespread awareness of moisture-related failures of some engineered materials; these failures have led to the filing of national- and state-level class action lawsuits against several manufacturers.
Thus, if pulp fiber-cement composites are to be used for exterior structural applications, the effects of cyclical wet/dry (rain/heat) exposure on performance must be known. Pulp fiber-cement composites have been tested in flexure to examine the progression of strength and toughness degradation. Based on scanning electron microscopy (SEM), environmental scanning electron microscopy (ESEM), energy dispersive spectroscopy (EDS), a three-part model describing the mechanisms of progressive degradation has been proposed: (1) initial fiber-cement/fiber interlayer debonding, (2) reprecipitation of crystalline and amorphous ettringite within the void space at the former fiber-cement interface, and (3) fiber embrittlement due to reprecipitation of calcium hydroxide filling the spaces within the fiber cell wall structure.
Finally, as a means to mitigate kraft pulp fiber-cement composite degradation, the effects of partial portland cement replacement with various supplementary cementitious materials (SCMs) has been investigated for their effect on mitigating kraft pulp fiber-cement composite mechanical property degradation (i.e., strength and toughness losses) during wet/dry cycling. SCMs have been found to be effective in mitigating composite degradation through several processes, including a reduction in the calcium hydroxide content, stabilization of monosulfate by maintaining pore solution pH, and a decrease in ettringite reprecipitation accomplished by increased binding of aluminum in calcium aluminate phases and calcium in the calcium silicate hydrate (C-S-H) phase.
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Effects from Alkali-Silica Reacton and Delayed Ettringite Formation on Reinforced Concrete Column Lap SplicesEck, Mary 2012 May 1900 (has links)
Reinforced concrete bridge columns can deteriorate prematurely due to the alkali-silica reaction (ASR) and/or delayed ettringite formation (DEF), causing internal expansion and cracking on the surface of the concrete. The performance of the longitudinal reinforcement lap splice in deteriorated concrete columns is the focus in this research.
This thesis presents the results from the deterioration of large-scale specimens constructed and placed in an environment susceptible to ASR/DEF deterioration, the experimental results from four-point and three-point structural load tests, and an analytical model based on bending theory characterizing the specimen behavior during the structural load tests.
Fourteen large-scale specimens were constructed, placed in an environment to accelerate the ASR/DEF deterioration mechanisms, and instrumented both internally and externally to measure the internal concrete expansions, and surface expansions and crack widths. In addition, two control specimens were constructed and kept in a laboratory, preventing ASR/DEF deterioration. Post-tensioning was used to simulate axial load on a bridge column. Structural load tests were performed on eight specimens with no ASR/DEF damage to late stage ASR and minimal DEF damage. Comparing the specimen behaviors during the loading testing, it was found that the yield strength increased about 5-15%, and post-cracking stiffness up to first yielding of the deteriorated specimens was about 25-35% stiffer than the control specimens. The increased specimen strength and stiffness likely occurred from volumetric expansion due to ASR/DEF damage which engaged the reinforcement, further confining the concrete and causing a beneficial increase in the axial post-tensioning load. The analytical model matched the control specimens well and matched the non-control specimens when the axial load was increased.
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