11 |
Caracterização do resíduo de resina epóxi com fibra de vidro proveniente da fabricação de pás eólicas e sua incorporação em argamassa de cimento Portland / Characterization of epoxy resin residue with glass fiber from the manufacture of wind blades and its incorporation in Portland cement mortarOliveira, Paulo Silas [UNESP] 20 September 2017 (has links)
Submitted by PAULO SILAS OLIVEIRA (paulo_pso@hotmail.com) on 2017-09-21T18:32:52Z
No. of bitstreams: 1
DISSERTAÇÃO PSO.pdf: 2528233 bytes, checksum: 9afc1a3039409fe2145077515d301f3d (MD5) / Approved for entry into archive by LUIZA DE MENEZES ROMANETTO (luizamenezes@reitoria.unesp.br) on 2017-09-26T13:50:38Z (GMT) No. of bitstreams: 1
oliveira_ps_me_soro.pdf: 2563476 bytes, checksum: 6fbd8ead3546cb380f44253aa8dd8ac3 (MD5) / Made available in DSpace on 2017-09-26T13:50:38Z (GMT). No. of bitstreams: 1
oliveira_ps_me_soro.pdf: 2563476 bytes, checksum: 6fbd8ead3546cb380f44253aa8dd8ac3 (MD5)
Previous issue date: 2017-09-20 / Dentre as diversas maneiras de se obter energia limpa, a energia eólica é o setor que esta em grande expansão, pois apresentou no Brasil, em 2015 um crescimento de 77,1% em comparação ao ano de 2014. Este crescimento acelerado traz juntamente uma enorme quantidade de resíduos gerados no processo de fabricação dos conjuntos geradores de energia. Um dos componentes dos conjuntos geradores é a pá eólica, confeccionada basicamente de uma estrutura, envolta por resina epóxi, fibra de vidro, madeira e cola. Uma empresa localizada na cidade de Sorocaba, fabricante de pás eólicas, têm capacidade de produção de 200 pás/mês que gera uma quantidade considerável de resíduos. Este trabalho visa incorporar a resina epóxi misturada com fibra de vidro, que é um resíduo gerado na produção das pás eólicas, em argamassa fabricada com cimento Portland CPII F32, com o objetivo de utilizar o resíduo substituindo parcialmente a areia empregada, pois desta forma há possibilidade de redução do descarte em aterros, e também diminuição da utilização de recursos naturais. Inicialmente o resíduo coletado na forma sólida, foi transformado em pó através do processo de torneamento, este pó foi caracterizado pelas técnicas de ângulo de contato, massa específica, teor de inorgânicos, granulometria, Difração de Raios X (DRX), Microscopia Eletrônica de Varredura (MEV) e Espectroscopia de Raios X por Dispersão em Energia (EDS). Posterior às caracterizações, foram confeccionados corpos de prova cimentícios com diversas proporções de substituição da areia pelo resíduo, além de um corpo de prova (CP) sem adição. Seguido da confecção dos CP foram realizados ensaios de tração na flexão, compressão, absorção de água, índice de vazios, microscopia ótica e massa específica das argamassas. Os resultados atestaram aprovação nos critérios de resistência mecânica (8 MPa), quando o resíduo substitui até 15% da areia, além de apresentar redução de massa específica, sendo vantajosa a aplicação na construção civil. / Among the various ways to obtain clean energy, wind power has been growing rapidly. In Brazil, the use of wind power grew 77.1% in 2015 compared with the previous year. This growth results in an enormous additional amount of residue produced during the manufacture of wind power generators. Wind turbine blades, which play an important role in the whole system, are made of a structure covered with epoxy resin, fiberglass, wood and glue. A company that manufactures wind power generators located in Sorocaba can produce up to 200 wind blades per month, which produces a considerable amount of residue. This project aims to incorporate epoxy resin together with fiberglass, which is also used in the production of such blades, into mortar made with Portland CPII F32 cement; that is to substitute residue for part of the sand used in this process, so that the quantity of residue (waste) can be reduced, and consequently also reduce the use of natural resources. Initially, this residue was collected in its solid form, and then turned into powder using the turning process for milling. This powder was characterized by contact angle and specific mass measurements, determination of inorganic elements, granulometry, X-ray diffraction, Scanning Electron Microscopy (SEM) and Energy Dispersive X-ray Spectroscopy (EDS). After the characterizations, some cement specimens were made with different quantities of residue substituting the sand, as well as a specimen (CP) without any substitution. Tests were then carried out, including resistance to bending traction and compression; determination of water absorption, void indices and of specific mass. The specimens showed positive results, having passed the mechanical resistance test (8MPa), when residue substituted up to 15% of the sand was substituted. In addition, the tests showed that the specific mass was also reduced, making it advantageous in applications in Civil Engineering.
|
12 |
Water Quality, Aesthetic, and Corrosion Inhibitor Implications of Newly Installed Cement Mortar Lining Used to Rehabilitate Drinking Water PipelinesClark, David D. 15 June 2009 (has links)
For decades, cement mortar relining has been used successfully to extend the life of drinking water pipelines, although, few quantitative data exist on the short-term water quality impacts of this process. This study investigated mortar lining impacts on disinfectant by-product formation, alkalinity, metal leaching, pH and disinfectant consumption, and odor generation shortly after in-situ installation. The experimental design used a 30-day, coupon immersion procedure that simulated a relined 4-inch diameter pipe located in a low-flow system. Four water regimes were utilized; no disinfectant, chlorine (2 mg/L at pH 6 .5 and 8), and chloramines. Flavor Profile Analysis panels evaluated odors of samples and controls. Additionally, the affects of three different phosphate-based corrosion prevention additive regimes were evaluated. Cement mortar leachates impacted water quality significantly during the first week of exposure. Alkalinity, hardness and pH increased dramatically after initial exposure, rising to approximately 600 mg/L as CaCO3 alkalinity, 770 mg/L as CaCO3 hardness, and pH 12 in the first two days. Sharp declines in alkalinity and hardness did not occur until after day 9 when the cement mortar was substantially cured and release of calcium hydroxide lessened. Chlorinated water residual disinfectant decay rate was increased substantially during the initial 24 hours and remained elevated until day 9. After day 1, there was not a significant increase in the formation of regulated haloacetic acids or trihalomethanes. Significant levels of aluminum (< 700 ug/L) and chromium (< 75 ug/L) were released at various times during the test period but their concentrations did not exceed USEPA water quality standards. Cement odor intensity levels were significantly higher than controls, persisted for 14 days, and were of an intensity that would be readily noticeable to consumers. The polyphosphate-based corrosion preventative resulted in less severe water quality effects than other phosphate additives or water without added phosphate. / Master of Science
|
13 |
Exploring the flowability, physical, and mechanical properties of eco-friendly colored cement mortars with metakaolin under sulfuric (H2SO4) and nitric acid (HNO3) attacksAkbulut, Z.F., Guler, S., Osmanoglu, F., Kivanc, M.R., Ashour, Ashraf 26 July 2024 (has links)
Yes / This article aims to investigate the flowability, physical, mechanical, and durability properties of metakaolin (MK)-added colored cement mortars exposed to the effects of H2SO4 sulfuric acid (SA) and HNO3 nitric acid (NA). MK was used in 20% replacement with cement, and yellow (YP) and red pigments (RP) were added to the mixtures at 1% and 3% of the cement by weight. According to the results, although MK reduced the workability and, therefore, the flow diameter (FD) of mortars, thanks to the void-filling feature of MK, filling the voids in the microstructure caused the samples' apparent porosity (AP) and relative dynamic modulus of elasticity (RDME) to decrease. Additionally, MK significantly improved the residual compressive (RCS) and residual flexural strengths (RFS) of the samples thanks to the calcium-silicate-hydrate (C-S-H) bonds it formed in the interior structure, owing to its high pozzolanic efficiency. Moreover, this improvement of MK is more remarkable in samples that remain subject to SA and NA attacks for more time.
Furthermore, while YP reduces the workability of mortars and, therefore, the FD value due to its needle-tipped grain structure, RP increases the FD value of the mortars with its spherical grain structure. However, YP and RP contributed to reducing the AP of the samples and increasing RCS and RFS capacities at a meager rate by showing a micro-filling effect. In addition, there were significant increases in the total color changes (E) of YP and RP-added colored mortar samples, especially after longer SA and NA attacks. / This paper is financially supported by the University of Van Yüzüncü Yil, Department of BAP, within the scope of the CDS-2023-10468 project. / The full-text of this article will be released for public view at the end of the publisher embargo on 4 May 2025.
|
14 |
Monitoring damage of concrete beams via self-sensing cement mortar coating with carbon nanotube-nano carbon black composite fillersQiu, L., Li, L., Ashour, Ashraf, Ding, S., Zhang, L., Han, B. 01 December 2023 (has links)
Yes / Self-sensing concrete used in coating form for structural health monitoring of concrete structures has the merits of cost-effectiveness, offering protective effect on structural components, enabling electrical measurements unaffected by steel reinforcement and is also convenient to maintain and replace. This paper investigates the feasibility of using self-sensing cement mortar coating containing carbon nanotube-nano carbon black (CNT-NCB) composite fillers (CNCFs) for damage monitoring of concrete beams. The self-sensing cement mortar coated to concrete beams demonstrated outstanding electrical conductivity (resistivity ranging from 18 to 85 Ω·cm). Under monotonic flexural loadings, self-sensing cement mortar coating with 1.8 vol.% CNCFs featured sensitive self-sensing performance in terms of capturing the initiation of vertical cracks at pure bending span of concrete beams, with fractional change in resistivity (FCR) reaching up to 60.6%. Moreover, FCR variations of self-sensing cement mortar coating exhibited good synchronization and stability with the variation of mid-span deflections of concrete beams during cyclic flexural loadings irrespective of the contents of CNCFs and cyclic amplitudes. Remarkably, it was found that FCR of cement mortar coating basically showed a progressive upward tendency, representing irreversible increase in the resistance during cyclic loading. The irreversible residual FCR indicated the crack occurrence and damage accumulation of concrete beams.
|
15 |
Monitoring damage of concrete beams via self-sensing cement mortar coating with carbon nanotube-nano carbon black composite fillersQiu, L., Li, L., Ashour, Ashraf, Ding, S., Han, B. 26 July 2024 (has links)
Yes / Self-sensing concrete used in coating form for structural health monitoring of concrete structures has the merits of cost-effectiveness, offering protective effect on structural components, enabling electrical measurements unaffected by steel reinforcement and is also convenient to maintain and replace. This paper investigates the feasibility of using self-sensing cement mortar coating containing carbon nanotube-nano carbon black (CNT-NCB) composite fillers (CNCFs) for damage monitoring of concrete beams. The self-sensing cement mortar coated to concrete beams demonstrated outstanding electrical conductivity (resistivity ranging from 18 to 85 Ω·cm). Under monotonic flexural loadings, self-sensing cement mortar coating with 1.8 vol.% CNCFs featured sensitive self-sensing performance in terms of capturing the initiation of vertical cracks at pure bending span of concrete beams, with fractional change in resistivity (FCR) reaching up to 60.6%. Moreover, FCR variations of self-sensing cement mortar coating exhibited good synchronization and stability with the variation of mid-span deflections of concrete beams during cyclic flexural loadings irrespective of the contents of CNCFs and cyclic amplitudes. Remarkably, it was found that FCR of cement mortar coating basically showed a progressive upward tendency, representing irreversible increase in the resistance during cyclic loading. The irreversible residual FCR indicated the crack occurrence and damage accumulation of concrete beams. / National Science Foundation of China (52368031, 51978127 and 52178188) and the China Postdoctoral Science Foundation (2022M710973)
|
16 |
Evaluation Of Cement Mortars By UltrasoundPaksoy, Nesibe Gozde 01 January 2006 (has links) (PDF)
Ultrasonic testing of concrete is often used for the assessment of its uniformity, strength, modulus of elasticity, durability and etc. therefore, the related parameters of testing such as the transducer frequency, the specimen geometry and etc. are well-known. On the other hand, most of the concrete properties are affected by the cement and the mechanical as well as some durability properties of cements are determined through cement mortars. Applications of ultrasound on determining the properties of cement mortars are quite limited. Therefore, the required specimen dimensions, transducer frequencies have not yet been established for cement mortars.
In this study, ultrasonic pulse velocity (UPV) of mortars was determined with different transducers of different frequencies for different size ans shape of specimens. Within the scope of the experimental program, three different ultrasonic frequencies (54 kHz, 82 kHz, and 150 kHz) were utilized and the relation between ultrasonic testing frequency and specimen shape was experimentally investigated.
It was concluded that the mechanical properties of mortar was adversely affected by the water-to-cement ratio. It was also observed that, when the length/wavelength ratio increases, the measured UPV with different transducer frequencies tends to converge to a single value. Finally, it was also concluded that an increase in moisture content of the mortar mixtures causes an increase in UPV and a decrease in compressive strength.
|
17 |
[en] RECYCLING OF PET BOTTLES, AIMING AT SUBSTITUTION OF SMALL AGGREGATE IN MORTAR / [pt] RECICLAGEM DE PET, VISANDO A SUBSTITUIÇÃO DE AGREGADO MIÚDO EM ARGAMASSASSUSAN SALES CANELLAS 28 October 2005 (has links)
[pt] O desenvolvimento de tecnologias que utilizem energias
limpas e a gestão
integrada dos resíduos domiciliares e industriais visando
uma reengenharia nos
conceitos sócio-empresariais é uma necessidade urgente. A
sociedade,
principalmente nos países desenvolvidos, prioriza produtos
de empresas que
possuam atividades socialmente corretas. A indústria da
construção civil, como
uma das maiores geradoras de resíduos, podendo chegar a
3000 kg/hab.ano,
não pode se eximir desta atitude. Uma vez que consome
grandes quantidades
de recursos naturais, um grande número de estudos para
substituição de bens
naturais não renováveis está sendo realizado nesse setor,
aliando materiais
convencionais com resíduos industriais e urbanos. Um dos
materiais que vem
sendo utilizado nestas pesquisas são as embalagens pós-
consumo de PET (
polietileno tereftalato ), resíduos que estão atingindo
percentuais cada vez
maiores na composição do lixo urbano, com presença
crescente no meio
ambiente. Esse trabalho visa apontar uma nova perspectiva
de utilização desse
material, propondo a substituição parcial da areia
natural, por material granulado
oriundo de garrafas de PET, objetivando a produção de
argamassas para uso
na construção civil. No presente estudo, foram realizadas
substituições nas
proporções de 10, 30 e 50% , tendo sido observado a melhor
possibilidade de
utilização do percentual de 30%, devido a não ter
apresentado perdas
significativas na plasticidade e nas resistências a
compressão e a tração. Foi
possível concluir que o compósito obtido tem potencial
para ser utilizado na
confecção de artefatos de concreto, sem grande
responsabilidade estrutural e
em mobiliários urbanos, além de seu uso permitir uma
economia significativa de
volumes de areia lavada, um recurso natural cuja extração
tem causado grandes danos ao ecossistema dos rios e suas
margens. / [en] The development of technology that uses clean energy and
the integrated
management of domestic and industrial residues aiming at a
new engineering in
the social and company relationship, is a urgent
necessity. The society, mainly
in developed countries, are already giving priority to the
products of companies
that possess identity with socially correct activities.
The industry of construction,
as one of the larger generator of residues, that produces
around
3000kg/hab.year, and can not exempt of this purpose. Since
the civil
construction consumes great amount of natural sector
resources, a large
number of studies aiming at the substitution of natural
sand, considered a non
renewable material, is being carried out, particularly by,
mixing conventional
material with industrial and urban residues. The material
used in these this
study, was granulated PET (polyethylene tereftalate),
obtained from beverage
bottles, residues that are reaching a high percentage in
the composition of the
urban wastes. The objective of this research aimed at
create a new perspective
for construction materials, by crushing bottles of PET and
using the produced
material as a substitute of the natural sands for
production of mortar. In this
study was used the PET/sand ratios of 10, 30 and 50%,
being 30%, the best
ratio observed, due to a still good workability, an
acceptable compressive and
tensile strengths. The innovation, proposed in this study
for instance, in the
production of pieces of concrete, without great structural
value, and in urban
furnitureleading to a significant economy of volumes of
sands, a resource
whose extraction has been caused great damages to the
present ecosystem of
the rivers and in its edges.
|
18 |
Effect of temperature on the sustainability of eco-engineered cementitious composites: curing, extreme conditions and service lifeVito Francioso (12419578) 14 April 2022 (has links)
<p>With over 30 billion tons of global annual production, concrete is the most used construction material in the world. Its manufacturing is associated with a strong environmental impact due to the high natural resources’ consumption, energy consumption, and a large generation of wastes and pollutants with significant global consequences. There are many different approaches to reduce the environmental impact of cementitious materials. Two examples are: (i) the use of recycled aggregate (RA) such as recycled concrete aggregate (RCA) and recycled plastics, or supplementary cementitious materials (SCMs) such as biomass ashes to reduce the use of natural aggregates and cement, respectively, and (ii) using nano-additives (for instance, nano-TiO2) to enhance material’s performance and to provide the material new properties that may have a positive proactive effect during its service life (i.e., photocatalytic properties that may reduce different pollutants concentrations from the environment). These approaches have been widely studied in standard conditions. However, boundary conditions such as temperature or moisture can be critical factors that directly or indirectly affect the effect of these approaches on the sustainability of cementitious composites in all stages of their life, from curing to service conditions.</p>
<p>It is known that curing temperature influences the effect of using recycled materials (such as RCA or SCMs) on the mechanical properties of cementitious materials. However, there were no studies concerning the influence of curing temperature on the nano-TiO2 addition effect on mechanical properties of cementitious composites. A potential change will affect composites’ sustainability; if curing temperature influences the effect of nano-TiO2 on strength, the cement content needed to achieve a given performance will variate. This study concluded that curing temperature is a key factor that changes the effect of TiO2 nanoparticles on mechanical properties and pore structure of Portland cement mortars; the lower the curing temperature, the higher the positive effect of TiO2 on compressive strength.</p>
<p>Besides the use of nano-TiO2, the substitution of NA with RCA might significantly benefit the sustainability of cementitious composites. However, the use of RCA may lead to a reduction in strength. On the other hand, the addition of nano-TiO2 mixtures containing RCA might offset this reduction in strength. Nevertheless, studying their effects on the composites’ performance under extreme conditions is critical to assess the actual environmental impact since durability is one of the main pillars of cementitious materials sustainability. This study concluded that even though RCA may be beneficial to increase sustainability aspects in terms of net waste generation and natural abiotic depletion, its potential negative effects on high-temperature resistance should be considered to not lead to structural problems during its lifetime, especially if used in combination with nano-TiO2. The addition of low percentages of nano-TiO2 has a negative effect on the high-temperature resistance of mortar containing 100% RCA. Differences in thermal properties between old aggregate, old cement paste, and new cement paste with nano-TiO2 may induce internal stresses at high temperatures that can produce a failure at lower strength due to the weaker interfacial transition zone (ITZ) between the stronger new cement paste (with nano-TiO2) and the old cement paste. To the same extent, it is important to understand how extreme temperatures impact the effect of other recycled materials in cementitious composite performance. This study found that recycled polypropylene (re-PP) fibers may mitigate the strength loss caused by high-temperature exposure, enhance the residual flexural strength, and increase the energy absorption capability. The changes in the fiber-matrix ITZ after cooling observed through an optical microscope suggested that the mechanical improvements are related to an enhancement of the fiber-matrix ITZ after high-temperature exposure and cooling.</p>
<p>The next part of the dissertation focused on studying the thermal conductivity susceptibility to ambient conditions variation and how RCA substitution can affect this susceptibility. Understanding the effect of RCA on the thermal conductivity of cementitious composites would be crucial to assess their effects on the environmental impact during service life as part of a building component. Results showed that the higher percentage of porosity (due to RCA utilization) increases the susceptibility of thermal conductivity to moisture. Thus, actual moisture content and temperature should be considered when assessing the effect of RCA on thermal conductivity and its influence on sustainability in terms of energy savings when used as part of building envelops.</p>
<p>Finally, the last part of this dissertation focused on assessing the impact of curing temperature on the sustainability of sugarcane bagasse ash (SCBA) as a partial replacement of cement in mortars. An experimental campaign was performed to evaluate the effect of partial replacement of cement with SCBA on compressive strength as a function of curing temperature. Hence, a life cycle assessment (LCA) was performed from the extraction of the raw materials to the material production part of the life cycle, using as a functional unit 1 m3 of mortar with the same compressive strength as the reference mixture (plain Portland cement mortar without SCBA) cured at the same temperature. Results showed that a replacement of 97 kg of cement by SCBA (per m3 of mortar) may produce a reduction of the environmental impacts two times higher when the curing temperature was 45°C than when the temperature was 21°C. Results clearly indicate that the sustainability of SCBA utilization as a partial replacement for cement will be higher when mortar is poured in hot regions or during days with higher temperatures. Therefore, external curing temperature is an important factor that should be considered when assessing the sustainability of cementitious composites containing sugarcane biomass ashes.</p>
|
19 |
Studies on nonlinear mechanical wave behavior to characterize cement based materials and its durabilityEiras Fernández, Jesús Nuño 10 October 2016 (has links)
[EN] The test for determining the resonance frequencies has traditionally been used to investigate the mechanical integrity of concrete cores, to assess the conformity of concrete constituents in different accelerated durability tests, and to ascertain constitutive properties such as the elastic modulus and the damping factor. This nondestructive technique has been quite appealed for evaluation of mechanical properties in all kinds of durability tests. The damage evolution is commonly assessed from the reduction of dynamic modulus which is produced as a result of any cracking process. However, the mechanical behavior of concrete is intrinsically nonlinear and hysteretic. As a result of a hysteretic stress-strain behavior, the elastic modulus is a function of the strain. In dynamic tests, the nonlinearity of the material is manifested by a decrease of the resonance frequencies, which is inversely proportional to the excitation amplitude. This phenomenon is commonly referred as fast dynamic effect. Once the dynamic excitation ceases, the material undergoes a relaxation process whereby the elastic modulus is restored to that at rest. This phenomenon is termed as slow dynamics. These phenomena (fast and slow dynamics) find their origin in the internal friction of the material. Therefore, in cement-based materials, the presence of microcracks and interfaces between its constituents plays an important role in the material nonlinearity. In the context of the assessment of concrete durability, the damage evolution is based on the increase of hysteresis, as a result of any cracking process. In this thesis three different nondestructive techniques are investigated, which use impacts for exciting the resonant frequencies. The first technique consists in determining the resonance frequencies over a range of impact forces. The technique is termed Nonlinear Impact Resonant Acoustic Spectroscopy (NIRAS). It consists in ascertaining the downward resonant frequency shift that the material undergoes upon increasing excitation amplitude. The second technique consists in investigating the nonlinear behavior by analyzing the signal corresponding to a single impact. This is, to determine the instantaneous frequency, amplitude and attenuation variations corresponding to a single impact event. This technique is termed as Nonlinear Resonant Acoustic Single Impact Spectroscopy (NSIRAS). Two techniques are proposed to extract the nonlinear behavior by analyzing the instantaneous frequency variations and attenuation over the signal ring down. The first technique consists in discretizing the frequency variation with time through a Short-Time Fourier Transform (STFT) based analysis. The second technique consists of a least-squares fit of the vibration signals to a model that considers the frequency and attenuation variations over time. The third technique used in this thesis can be used for on-site evaluation of structures. The technique is based on the Dynamic Acousto- Elastic Test (DAET). The variations of elastic modulus as derived through NIRAS and NSIRAS techniques provide an average behavior and do not allow derivation of the elastic modulus variations over one vibration cycle. Currently, DAET technique is the only one capable to investigate the entire range of nonlinear phenomena in the material. Moreover, unlike other DAET approaches, this study uses a continuous wave source as probe. The use of a continuous wave allows investigation of the relative variations of the elastic modulus, as produced by an impact. Moreover, the experimental configuration allows one-sided inspection. / [ES] El ensayo de determinación de las frecuencias de resonancia ha sido tradicionalmente empleado para determinar la integridad mecánica de testigos de hormigón, en la evaluación de la conformidad de mezclas de hormigón en diversos ensayos de durabilidad, y en la terminación de propiedades constitutivas como son el módulo elástico y el factor de amortiguamiento. Esta técnica no destructiva ha sido ampliamente apelada para la evaluación de las propiedades mecánicas en todo tipo de ensayos de durabilidad. La evolución del daño es comúnmente evaluada a partir de la reducción del módulo dinámico, producido como resultado de cualquier proceso de fisuración. Sin embargo, el comportamiento mecánico del hormigón es intrínsecamente no lineal y presenta histéresis. Como resultado de un comportamiento tensión-deformación con histéresis, el módulo elástico depende de la deformación. En ensayos dinámicos, la no linealidad del material se manifiesta por una disminución de las frecuencias de resonancia, la cual es inversamente proporcional a la amplitud de excitación. Este fenómeno es normalmente denominado como dinámica rápida. Una vez la excitación cesa, el material experimenta un proceso de relajación por el cual, el módulo elástico es restaurado a aquel en situación de reposo. Este fenómeno es denominado como dinámica lenta. Estos fenómenos ¿dinámicas rápida y lenta¿ encuentran su origen en la fricción interna del material. Por tanto, en materiales basados en cemento, la presencia de microfisuras y las interfaces entre sus constituyentes juegan un rol importante en la no linealidad mecánica del material. En el contexto de evaluación de la durabilidad del hormigón, la evolución del daño está basada en el incremento de histéresis, como resultado de cualquier proceso de fisuración. En esta tesis se investigan tres técnicas diferentes las cuales utilizan el impacto como medio de excitación de las frecuencias de resonancia. La primera técnica consiste en determinar las frecuencias de resonancia a diferentes energías de impacto. La técnica es denominada en inglés: Nonlinear Impact Resonant Acoustic Spectroscopy (NIRAS). Ésta consiste en relacionar el detrimento que el material experimenta en sus frecuencias de resonancia, con el aumento de la amplitud de la excitación. La segunda técnica consiste en investigar el comportamiento no lineal mediante el análisis de la señal correspondiente a un solo impacto. Ésta consiste en determinar las propiedades instantáneas de frecuencia, atenuación y amplitud. Esta técnica se denomina, en inglés, Nonlinear Single Impact Resonant Acoustic Spectroscopy (NSIRAS). Se proponen dos técnicas de extracción del comportamiento no lineal mediante el análisis de las variaciones instantáneas de frecuencia y atenuación. La primera técnica consiste en la discretización de la variación de la frecuencia con el tiempo, mediante un análisis basado en Short-Time Fourier Transform (STFT). La segunda técnica consiste en un ajuste por mínimos cuadrados de las señales de vibración a un modelo que considera las variaciones de frecuencia y atenuación con el tiempo. La tercera técnica empleada en esta tesis puede ser empleada para la evaluación de estructuras in situ. La técnica se trata de un ensayo acusto-elástico en régimen dinámico. En inglés Dynamic Acousto-Elastic Test (DAET). Las variaciones del módulo elástico obtenidas mediante los métodos NIRAS y NSIRAS proporcionan un comportamiento promedio y no permiten derivar las variaciones del módulo elástico en un solo ciclo de vibración. Actualmente, la técnica DAET es la única que permite investigar todo el rango de fenómenos no lineales en el material. Por otra parte, a diferencia de otras técnicas DAET, en este estudio se emplea como contraste una onda continua. El uso de una onda continua permite investigar las variaciones relativas del módulo elástico, para una señal transito / [CA] L'assaig de determinació de les freqüències de ressonància ha sigut tradicionalment empleat per a determinar la integritat mecànica de testimonis de formigó, en l'avaluació de la conformitat de mescles de formigó en diversos assajos de durabilitat, i en la terminació de propietats constitutives com són el mòdul elàstic i el factor d'amortiment. Esta tècnica no destructiva ha sigut àmpliament apel·lada per a l'avaluació de les propietats mecàniques en tot tipus d'assajos de durabilitat. L'evolució del dany és comunament avaluada a partir de la reducció del mòdul dinàmic, produït com resultat de qualsevol procés de fisuración. No obstant això, el comportament mecànic del formigó és intrínsecament no lineal i presenta histèresi. Com resultat d'un comportament tensió-deformació amb histèresi, el mòdul elàstic depén de la deformació. En assajos dinàmics, la no linealitat del material es manifesta per una disminució de les freqüències de ressonància, la qual és inversament proporcional a l'amplitud d'excitació. Este fenomen és normalment denominat com a dinàmica ràpida. Una vegada l'excitació cessa, el material experimenta un procés de relaxació pel qual, el mòdul elàstic és restaurat a aquell en situació de repòs. Este fenomen és denominat com a dinàmica lenta. Estos fenòmens --dinámicas ràpida i lenta troben el seu origen en la fricció interna del material. Per tant, en materials basats en ciment, la presència de microfissures i les interfícies entre els seus constituents juguen un rol important en la no linealitat mecànica del material. En el context d'avaluació de la durabilitat del formigó, l'evolució del dany està basada en l'increment d'histèresi, com resultat de qualsevol procés de fisuración. En esta tesi s'investiguen tres tècniques diferents les quals utilitzen l'impacte com a mitjà d'excitació de les freqüències de ressonància. La primera tècnica consistix a determinar les freqüències de ressonància a diferents energies d'impacte. La tècnica és denominada en anglés: Nonlinear Impact Resonant Acoustic Spectroscopy (NIRAS). Esta consistix a relacionar el detriment que el material experimenta en les seues freqüències de ressonància, amb l'augment de l'amplitud de l'excitació. La segona tècnica consistix a investigar el comportament no lineal per mitjà de l'anàlisi del senyal corresponent a un sol impacte. Esta consistix a determinar les propietats instantànies de freqüència, atenuació i amplitud. Esta tècnica es denomina, en anglés, Nonlinear Single Impact Resonant Acoustic Spectroscopy (NSIRAS). Es proposen dos tècniques d'extracció del comportament no lineal per mitjà de l'anàlisi de les variacions instantànies de freqüència i atenuació. La primera tècnica consistix en la discretización de la variació de la freqüència amb el temps, per mitjà d'una anàlisi basat en Short-Time Fourier Transform (STFT). La segona tècnica consistix en un ajust per mínims quadrats dels senyals de vibració a un model que considera les variacions de freqüència i atenuació amb el temps. La tercera tècnica empleada en esta tesi pot ser empleada per a l'avaluació d'estructures in situ. La tècnica es tracta d'un assaig acusto-elástico en règim dinàmic. En anglés Dynamic Acousto-Elastic Test (DAET). Les variacions del mòdul elàstic obtingudes per mitjà dels mètodes NIRAS i NSIRAS proporcionen un comportament mitjà i no permeten derivar les variacions del mòdul elàstic en un sol cicle de vibració. Actualment, la tècnica DAET és l'única que permet investigar tot el rang de fenòmens no lineals en el material. D'altra banda, a diferència d'altres tècniques DAET, en este estudi s'empra com contrast una ona contínua. L'ús d'una ona contínua permet investigar les variacions relatives del mòdul elàstic, per a un senyal transitori. A més, permet la inspecció d'elements per mitjà de l'accés per una sola cara. / Eiras Fernández, JN. (2016). Studies on nonlinear mechanical wave behavior to characterize cement based materials and its durability [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/71439 / Premios Extraordinarios de tesis doctorales
|
Page generated in 0.0745 seconds