Effect of Fiber Morphology on Tensile Properties of Polypropylene Cement Composites

January 2017

abstract: The main objective of this study is to investigate the effect of polypropylene fiber morphology on the tensile response of cementitious composites. Two proprietary polypropylene fibers manufactured by BASF – MAC 2200CB, a crimped monofilament macro fiber and MF40, a bundled multi filament polypropylene made up of 500 filaments,40-micron diameter each were compared. The stiff structure and crimped geometry of MAC 2200 CB was studied in comparison with the multifilament MF40, which provide a higher surface area and a bundled fiber effect. Uniaxial tensile tests were performed on individual fibers to study fiber strength and failure pattern at three different gage lengths. The interaction of these 2 fibers with cement matrix was studied under varying strain rate, embedded fiber length and matrix mixes by a series of quassi - static fiber pullout tests. Unidirectional filament wound composite laminates were manufactures with the two fibers and only MF40 woven textiles were used to manufacture MF40 textile reinforced composites. The mechanical behavior of polypropylene fiber and textile reinforced cementitious composites subjected to static tensile loading with the effects of fiber type and dosage, textile weave and dosage, matrix formulations, processing techniques etc. is studied. Evolution of distributed cracking mechanism and local strain fields was documented using digital image correlation (DIC) and correlated with the tensile response and stiffness degradation. VIC 3D-7, commercial software developed by Correlated Solutions, Inc. was used to run the DIC analysis for the tensile tests on laminates. The DIC technique was further used for automated determination of crack density, crack spacing, and characterizing damage evolution. / Dissertation/Thesis / Masters Thesis Civil Engineering 2017

Civil engineering

Fiber Reinforced Cement Composites

Estudio de compuestos de GRC y adiciones activas: Propiedades mecánicas, envejecimiento acelerado y durabilidad

Lalinde Castrillón, Luis Felipe

21 December 2020

[ES] En el ámbito de los materiales compuestos o composites para la construcción, el cemento reforzado con fibras de vidrio (GRC, del inglés glass fiber reinforced cement) es el más extensamente utilizado, por sus excelentes propiedades mecánicas (resistencia a flexión y tenacidad). Sin embargo, la durabilidad de estos composites se ha demostrado crítica, y es necesario proponer alternativas. Las fibras usadas, de carácter álcali-resistente (fibras AR, formadas por agrupación de filamentos), son atacadas por el medio agresivo que impone el cemento hidratado. Una alternativa interesante, desde el punto de vista tecnológico, es la incorporación de materiales cementantes suplementarios de carácter puzolánico. El objetivo del presente trabajo es estudiar la influencia de las diferentes adiciones activas en morteros de GRC, observando el comportamiento de los elementos constitutivos del material en condiciones normales de curado, y también al ser sometidos a procesos de envejecimiento controlado. Asimismo, se analiza el comportamiento de los nuevos composites sometidos a diferentes medios agresivos, evaluando la durabilidad y la mejora de los compuestos por medio de la determinación de sus propiedades mecánicas, químicas y físicas. Se han elaborado probetas de GRC a través del procedimiento de premezcla (premix) y se han determinado sus propiedades mecánicas (resistencia a flexión, tenacidad y módulo de elasticidad). Adicionalmente, se han cuantificado las ganancias de resistencia al comparar composites GRC basados en cemento Portland (especímenes control) con otros en los que se ha sustituido hasta el 60% de dicho cemento por adiciones puzolánicas. Al objeto de mejorar la reactividad de las puzolanas, en algunos casos se ha implementado un aumento de su finura a través de la molienda (cenizas volantes molidas, CVm) o de procesos de sonicación (humo de sílice sonicado, HSS). Los especímenes de GRC han sido sometidos a un proceso de envejecimiento (tratamiento en agua a 55ºC durante un período prolongado) y se ha observado un empeoramiento muy importante de la resistencia a flexión y la tenacidad de aquellos que poseen solamente cemento Pórtland como componente cementante. Los composites GRC que contienen cantidades elevadas de puzolana (60% de CVm) o mezclas de puzolanas (50%CVm / 10%HSS, 50%CVm / 10%FCC) presentan una mejora sustancial de las propiedades mecánicas con respecto a los GRC control. La mejora de estos sistemas GRC con elevados porcentajes de puzolanas reactivas se han confirmado a través de estudios físicos y físico - químicos: evaluación de densidad, absorción, estudios microscópicos (lupa y microscopía electrónica de barrido) y análisis termogravimétrico. En cuanto a la respuesta de los composites GRC frente a diferentes disoluciones agresivas, se ha demostrado el efecto beneficioso de la presencia de puzolanas. Después de la exposición de los morteros de GRC a una disolución de NH4Cl, el comportamiento mecánico de los morteros puzolánicos se mantiene por encima del mortero GRC control: esto se debe a la relación directa existente con el incremento de la densidad y la disminución de grado de absorción del composite con la sustitución puzolánica. Al evaluar las propiedades de los morteros de GRC después de su exposición a una disolución de H2SO4, se observan diferencias muy importantes en la evolución de la masa, resistencia a flexión y tenacidad: los composites control son más afectados por la acidez del medio, de modo que la pérdida de masa es muy significativa si se compara con los GRC que presentan puzolanas. La estancia en la empresa Saint Gobain Vetrotex, ha permitido confirmar una gran similitud en los resultados obtenidos mediante los procedimientos seguidos en el laboratorio de la UPV (compuestos de GRC premezclado) comparados con las prácticas desarrolladas por el laboratorio de materiales de la empresa (composites de GRC proyectado). Se han evaluado / [CAT] En l'àmbit dels materials compostos o compòsits per a la construcció, el ciment reforçat amb fibres de vidre (GRC, de l'anglès glass fiber reinforced cement) és el més extensament utilitzat, per les seves excel·lents propietats mecàniques (resistència a flexió i tenacitat). No obstant això, la durabilitat d'aquests compòsits s'ha demostrat crítica, i cal proposar alternatives. Les fibres usades, de caràcter àlcali-resistent (fibres AR, formades per agrupació de filaments), són atacades pel medi agressiu que imposa el ciment hidratat. Una alternativa interessant des del punt de vista tecnològic és la incorporació de materials cimentants suplementaris de caràcter putzolànic. L'objectiu d'aquest treball és estudiar la influència de les diferents addicions actives en morters de GRC, observant el comportament dels elements constitutius del material en condicions normals de curat, i també quan son sotmesos a processos d'envelliment controlat. Així mateix, s'analitza el comportament dels nous compòsits sotmesos a diferents mitjans agressius, avaluant la durabilitat i la millora dels compostos mitjançant la determinació de les seves propietats mecàniques, químiques i físiques. S'han elaborat provetes de GRC a través del procediment de mescla prèvia (premix) i s'ha determinat les seves propietats mecàniques (resistència a flexió, tenacitat, mòdul d'elasticitat). Addicionalment s'han quantificat els guanys de resistència al comparar compòsits GRC basats en ciment Portland (espècimens control) amb altres en què s'ha substituït fins al 60% d'aquest ciment per materials putzolànics. A l'objecte de millorar la reactivitat de les putzolanes, en alguns casos s'ha implementat un augment de la seva finor a través de la mòlta (cendres volants mòltes, CVm) o de processos de sonicació (fum de sílice sonicat, HSS). Els espècimens de GRC han estat sotmesos a un procés d'envelliment (tractament en aigua a 55ºC durant un període prolongat) i s'ha observat l'empitjorament molt significatiu de la resistència a flexió i la tenacitat d'aquells que posseeixen solament ciment Pòrtland com a component cimentant. Els compòsits GRC que contenen quantitats elevades de putzolana (60% de CVm) o mescles de putzolanes (50% CVm / 10% HSS, 50% CVm / 10% FCC) presenten una millora substancial de les propietats mecàniques respecte als GRC control. La millora d'aquests sistemes GRC amb elevats percentatges de putzolanes reactives s'han confirmat a través d'estudis físics i fisicoquímics: avaluació de densitat, absorció, estudis microscòpics (lupa i microscòpia electrònica de rastreig) i anàlisi termogravimètric. Pel que fa a la resposta dels compòsits GRC enfront de diferents dissolucions agressives, s'ha demostrat l'efecte beneficiós de la presència de putzolanes. Després de l'exposició dels morters de GRC a una dissolució de NH4Cl, el comportament mecànic dels morters putzolànics es millor que el morter GRC control: això es deu a la relació directa existent amb l'increment de la densitat i la disminució del grau d'absorció del compòsit amb la putzolana. Quan s¿ha avaluat les propietats dels morters de GRC després de la seva exposició a una dissolució H2SO4, s'observen diferències molt importants en l'evolució de la massa, resistència a flexió i tenacitat: els compòsits control són més afectats per l'acidesa del medi, de manera que la pèrdua de massa és molt significativa si es compara amb els GRC que presenten putzolanes. L'estada a l'empresa Saint Gobain Vetrotex, ha permès confirmar una gran similitud en els resultats obtinguts mitjançant els procediments seguits en el laboratori de la UPV (compostos de GRC amb premescla) comparats amb les pràctiques desenvolupades pel laboratori de materials de l'empresa (compostos de GRC projectat). S'han avaluat prototips per a la indústria de l'GRC projectat. / [EN] In the field of composite materials for construction, glass fiber reinforced cement (GRC) is the most widely used, due to its excellent mechanical properties (resistance to bending and toughness). However, the durability of these composites has been demonstrated to be critical and alternatives need to be proposed. The used fibers, alkali-resistant (AR fibers, formed by grouping of filaments), are attacked by the aggressive medium imposed by the hydrated cement. An interesting alternative, from a technological point of view, is the incorporation of supplementary cementitious materials of pozzolanic behaviour. The purpose of this research is to study the influence of the different mineral additions in GRC mortars, observing the behaviour of the constituent elements of the material under normal curing conditions and controlled aging processes. Likewise, the behaviour of new composites subjected to different aggressive environments is analyzed, evaluating the durability and improvement of the compounds by determining their mechanical, chemical and physical properties. GRC specimens have been produced through the premix procedure and their mechanical properties (flexural strength, toughness, and modulus of elasticity) have been determined. Additionally, resistance gains have been quantified when comparing GRC composites based on Portland cement (control specimens) with others in which up to 60% of that cement has been replaced by pozzolanic additions. In order to improve the reactivity of pozzolans, in some cases an increase in its fineness has been implemented through grinding (ground fly ash, CVm) or sonication processes (sonicated silica fume, HSS). The GRC specimens have been subjected to an aging process (treatment in water at 55ºC for an extended period) and worsening of the flexural strength and toughness of those who only have Portland cement as cementitious component has been observed. GRC composites containing high amounts of pozzolan (60% CVm) or mixtures of pozzolans (50% CVm / 10% HSS, 50% CVm / 10% FCC) show a substantial improvement in mechanical properties compared to the control GRC. The improvement of these GRC systems with high percentages of reactive pozzolans have been confirmed through physical and physical-chemical studies: evaluation of density, absorption, microscopic studies (magnifying glass and scanning electron microscopy), and thermogravimetric analysis. Regarding the response of GRC composites against different aggressive solutions, the beneficial effect of the presence of pozzolans has been demonstrated. After the exposure of the GRC mortars to a NH4Cl solution, the mechanical behavior of pozzolanic mortars remains above that of the control GRC mortar: this is due to the direct relationship existing with the increase in density and the decrease in the absorption of the composite with the pozzolanic replacement. When evaluating the properties of GRC mortars after exposure to an H2SO4 solution, very important differences are observed in the evolution of the mass, flexural strength and toughness: the control composites are more affected by the acidity of the medium, so that the loss of mass is very significant when compared to the GRCs that present pozzolans. The stay at the Saint Gobain Vetrotex company has confirmed a great similarity to the results obtained by the procedures followed at the UPV laboratory (premixed GRC compounds) compared to the practices developed by the company's materials laboratory (composites of projected GRC). Scalable prototypes have been assessed for the projected GRC industry. / Lalinde Castrillón, LF. (2020). Estudio de compuestos de GRC y adiciones activas: Propiedades mecánicas, envejecimiento acelerado y durabilidad [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/157637 / TESIS

Glass fibers

Reinforced cement

Fibra de vidrio

Cemento

Composites

Waste management

Glass fiber reinforced cement

Hormigón

Aprovechamiento de residuos

GRC

Durabilidad

Fibra de vidrio AR

INGENIERIA DE LA CONSTRUCCION

Contribuição ao estudo das propriedades dos materiais cimentícios reforçados com fibras de vidro (Glass Fibre Reinforced Cement - GRC) / Contribution to the study of properties of glass fibre reinforced cement - GRC

Lameiras, Rodrigo de Melo

January 2007

Os materiais cimentícios são materiais frágeis que apresentam resistências à tração e capacidades de deformação muito baixas. Uma das formas de contornar a fragilidade destes materiais é a utilização de fibras curtas, descontínuas e dispersas. Um exemplo destes materiais cimentícios são os produzidos com fibras de vidro, comumente denominados pela sigla GRC. Apesar dos diversos avanços apresentados na tecnologia do GRC, ele ainda apresenta uma degradação significativa das suas propriedades ao longo do seu envelhecimento. Além disso, por ser um material que começou a ser produzido em escala industrial há pouco tempo no Brasil, há uma carência de pesquisas que caracterizem os GRCs produzidos com materiais locais. Portanto, esta pesquisa veio com o objetivo geral de avaliar o GRC produzido com fibras de vidro álcali-resistente (tipo AR) e com os materiais disponíveis comercialmente na cidade de Porto Alegre com relação as suas propriedades mecânicas e durabilidade. Mais especificamente, estudou-se a influência do tamanho das fibras (35mm e 17,5mm), da adição de sílica ativa (5%) e metacaulim (5%, 10% e 15%), da relação agregado/cimento (1,00 e 1,10) e da idade (28, 42, 49 e 56 dias). As propriedades estudadas foram: limite de proporcionalidade (PEL), módulo de ruptura (MOR), índices de tenacidade (I5, I10 e I30), módulo de elasticidade na flexão (MEF), absorção de água (ABS), massa especifica (MES) e porosidade aparente (PAP). Além disso, utilizou-se um método acelerado de ataque em água a 50°C, em diversos períodos de ataque (14, 21 e 28 dias), para estudar o efeito do envelhecimento nas propriedades mecânicas do GRC. Os resultados mostraram que, enquanto algumas propriedades são majoritariamente dependentes da matriz, outras são fundamentalmente dependentes das propriedades do reforço. Apesar do aumento das fibras provocar melhorias na resistência última e na capacidade de absorção de energia do material, ele também gera pertubação naquelas propriedades que as características da matriz são mais relevantes devido ao fato das fibras dificultarem o adensamento do GRC. Com o uso de elevados teores de metacaulim, os compósitos produzidos com fibras curtas apresentaram MOR e índices de tenacidade elevados (também obtidos com fibras longas), mantendo o efeito benéfico do uso deste tamanho de fibras nas propriedades que dependem mais das matrizes. As propriedades majoritariamente dependentes das características das fibras (MOR, I5, I10 e I30) se mostraram muito sensíveis ao ataque. Ademais, o uso das adições pozolânicas não se mostrou capaz de reter tais propriedades para os tempos estudados. / The cementitious materials are fragile materials that show low tensile strengths and low capacity of deformation. One way of dealing with the fragility of these materials is the utilization of short, discontinuous and disperse fibres. One of these cementitious materials is the one usually called by the term GRC. Despite the advances of the GRC technology, this material shows high degradation of its properties throughout the life cycle. Besides that, the fact of being a material which has recently been produced in Brazil on a industrial scale, there is an enormous lack on researches about GRC produced with local materials. Therefore, this research was envisioned with the main objective of evaluating the GRC properties produced with alkali-resistent glass fibres (AR type) and with materials commercially available in Porto Alegre, analyzing its mechanical properties and durability. Specifically, it studied the influence of fibre length (35 mm and 17,5 mm), of silica fume (5%) and metakaolin addition (5%, 10% and 15%), of aggregate/cement relation (1,00 and 1,10) and of the age (28, 42, 49 and 56 days). The measured properties were: proportional limit (PEL), modulus of rupture (MOR), toughness indexes (I5, I10 and I30), modulus of elasticity in bending (MEF), water absorption (ABS), bulk density (MES) and apparent porosity (PAP). In addition, the mechanicals properties of GRC under the effect of ageing (stored in water at 50°C to accelerate the ageing) were investigated where the test were carried out after 14, 21 and 28 days of the accelerated ageing. The results showed that while some properties are mainly influenced by the matrix properties (PEL, MEF, ABS, MES and PAP), others are basically dependent on the fiber reinforcement properties (MOR, I5, I10 and I30). Despite the fact that GRC produced with greater fibre length showed increases at MOR and in energy absorption capacity, it lead to losses of those properties that are mainly influenced by the matrix because it is more difficult to consolidate this GRC. Furthermore, the addition of high contents of metakaolin in composites produced with short fibres leads to MOR and toughness indexes to the higher levels found (gotten with long fibres), keeping the benefic effect of using short fibres at the properties that are basically function of the matrix properties. The MOR, I5, I10 and I30 decreased when the GRC suffer accelerated ageing. The results also showed that the use of pozzolanic additions wasn't able to retain the mechanical properties of GRC throughout time

Fibras de vidro

Materiais de construção

Materiais compositos

GRC

Glass fibre

Fibre reinforced cement

Composites

Contribuição ao estudo das propriedades dos materiais cimentícios reforçados com fibras de vidro (Glass Fibre Reinforced Cement - GRC) / Contribution to the study of properties of glass fibre reinforced cement - GRC

Lameiras, Rodrigo de Melo

January 2007

Os materiais cimentícios são materiais frágeis que apresentam resistências à tração e capacidades de deformação muito baixas. Uma das formas de contornar a fragilidade destes materiais é a utilização de fibras curtas, descontínuas e dispersas. Um exemplo destes materiais cimentícios são os produzidos com fibras de vidro, comumente denominados pela sigla GRC. Apesar dos diversos avanços apresentados na tecnologia do GRC, ele ainda apresenta uma degradação significativa das suas propriedades ao longo do seu envelhecimento. Além disso, por ser um material que começou a ser produzido em escala industrial há pouco tempo no Brasil, há uma carência de pesquisas que caracterizem os GRCs produzidos com materiais locais. Portanto, esta pesquisa veio com o objetivo geral de avaliar o GRC produzido com fibras de vidro álcali-resistente (tipo AR) e com os materiais disponíveis comercialmente na cidade de Porto Alegre com relação as suas propriedades mecânicas e durabilidade. Mais especificamente, estudou-se a influência do tamanho das fibras (35mm e 17,5mm), da adição de sílica ativa (5%) e metacaulim (5%, 10% e 15%), da relação agregado/cimento (1,00 e 1,10) e da idade (28, 42, 49 e 56 dias). As propriedades estudadas foram: limite de proporcionalidade (PEL), módulo de ruptura (MOR), índices de tenacidade (I5, I10 e I30), módulo de elasticidade na flexão (MEF), absorção de água (ABS), massa especifica (MES) e porosidade aparente (PAP). Além disso, utilizou-se um método acelerado de ataque em água a 50°C, em diversos períodos de ataque (14, 21 e 28 dias), para estudar o efeito do envelhecimento nas propriedades mecânicas do GRC. Os resultados mostraram que, enquanto algumas propriedades são majoritariamente dependentes da matriz, outras são fundamentalmente dependentes das propriedades do reforço. Apesar do aumento das fibras provocar melhorias na resistência última e na capacidade de absorção de energia do material, ele também gera pertubação naquelas propriedades que as características da matriz são mais relevantes devido ao fato das fibras dificultarem o adensamento do GRC. Com o uso de elevados teores de metacaulim, os compósitos produzidos com fibras curtas apresentaram MOR e índices de tenacidade elevados (também obtidos com fibras longas), mantendo o efeito benéfico do uso deste tamanho de fibras nas propriedades que dependem mais das matrizes. As propriedades majoritariamente dependentes das características das fibras (MOR, I5, I10 e I30) se mostraram muito sensíveis ao ataque. Ademais, o uso das adições pozolânicas não se mostrou capaz de reter tais propriedades para os tempos estudados. / The cementitious materials are fragile materials that show low tensile strengths and low capacity of deformation. One way of dealing with the fragility of these materials is the utilization of short, discontinuous and disperse fibres. One of these cementitious materials is the one usually called by the term GRC. Despite the advances of the GRC technology, this material shows high degradation of its properties throughout the life cycle. Besides that, the fact of being a material which has recently been produced in Brazil on a industrial scale, there is an enormous lack on researches about GRC produced with local materials. Therefore, this research was envisioned with the main objective of evaluating the GRC properties produced with alkali-resistent glass fibres (AR type) and with materials commercially available in Porto Alegre, analyzing its mechanical properties and durability. Specifically, it studied the influence of fibre length (35 mm and 17,5 mm), of silica fume (5%) and metakaolin addition (5%, 10% and 15%), of aggregate/cement relation (1,00 and 1,10) and of the age (28, 42, 49 and 56 days). The measured properties were: proportional limit (PEL), modulus of rupture (MOR), toughness indexes (I5, I10 and I30), modulus of elasticity in bending (MEF), water absorption (ABS), bulk density (MES) and apparent porosity (PAP). In addition, the mechanicals properties of GRC under the effect of ageing (stored in water at 50°C to accelerate the ageing) were investigated where the test were carried out after 14, 21 and 28 days of the accelerated ageing. The results showed that while some properties are mainly influenced by the matrix properties (PEL, MEF, ABS, MES and PAP), others are basically dependent on the fiber reinforcement properties (MOR, I5, I10 and I30). Despite the fact that GRC produced with greater fibre length showed increases at MOR and in energy absorption capacity, it lead to losses of those properties that are mainly influenced by the matrix because it is more difficult to consolidate this GRC. Furthermore, the addition of high contents of metakaolin in composites produced with short fibres leads to MOR and toughness indexes to the higher levels found (gotten with long fibres), keeping the benefic effect of using short fibres at the properties that are basically function of the matrix properties. The MOR, I5, I10 and I30 decreased when the GRC suffer accelerated ageing. The results also showed that the use of pozzolanic additions wasn't able to retain the mechanical properties of GRC throughout time

Fibras de vidro

Materiais de construção

Materiais compositos

GRC

Glass fibre

Fibre reinforced cement

Composites

Contribuição ao estudo das propriedades dos materiais cimentícios reforçados com fibras de vidro (Glass Fibre Reinforced Cement - GRC) / Contribution to the study of properties of glass fibre reinforced cement - GRC

Lameiras, Rodrigo de Melo

January 2007

Os materiais cimentícios são materiais frágeis que apresentam resistências à tração e capacidades de deformação muito baixas. Uma das formas de contornar a fragilidade destes materiais é a utilização de fibras curtas, descontínuas e dispersas. Um exemplo destes materiais cimentícios são os produzidos com fibras de vidro, comumente denominados pela sigla GRC. Apesar dos diversos avanços apresentados na tecnologia do GRC, ele ainda apresenta uma degradação significativa das suas propriedades ao longo do seu envelhecimento. Além disso, por ser um material que começou a ser produzido em escala industrial há pouco tempo no Brasil, há uma carência de pesquisas que caracterizem os GRCs produzidos com materiais locais. Portanto, esta pesquisa veio com o objetivo geral de avaliar o GRC produzido com fibras de vidro álcali-resistente (tipo AR) e com os materiais disponíveis comercialmente na cidade de Porto Alegre com relação as suas propriedades mecânicas e durabilidade. Mais especificamente, estudou-se a influência do tamanho das fibras (35mm e 17,5mm), da adição de sílica ativa (5%) e metacaulim (5%, 10% e 15%), da relação agregado/cimento (1,00 e 1,10) e da idade (28, 42, 49 e 56 dias). As propriedades estudadas foram: limite de proporcionalidade (PEL), módulo de ruptura (MOR), índices de tenacidade (I5, I10 e I30), módulo de elasticidade na flexão (MEF), absorção de água (ABS), massa especifica (MES) e porosidade aparente (PAP). Além disso, utilizou-se um método acelerado de ataque em água a 50°C, em diversos períodos de ataque (14, 21 e 28 dias), para estudar o efeito do envelhecimento nas propriedades mecânicas do GRC. Os resultados mostraram que, enquanto algumas propriedades são majoritariamente dependentes da matriz, outras são fundamentalmente dependentes das propriedades do reforço. Apesar do aumento das fibras provocar melhorias na resistência última e na capacidade de absorção de energia do material, ele também gera pertubação naquelas propriedades que as características da matriz são mais relevantes devido ao fato das fibras dificultarem o adensamento do GRC. Com o uso de elevados teores de metacaulim, os compósitos produzidos com fibras curtas apresentaram MOR e índices de tenacidade elevados (também obtidos com fibras longas), mantendo o efeito benéfico do uso deste tamanho de fibras nas propriedades que dependem mais das matrizes. As propriedades majoritariamente dependentes das características das fibras (MOR, I5, I10 e I30) se mostraram muito sensíveis ao ataque. Ademais, o uso das adições pozolânicas não se mostrou capaz de reter tais propriedades para os tempos estudados. / The cementitious materials are fragile materials that show low tensile strengths and low capacity of deformation. One way of dealing with the fragility of these materials is the utilization of short, discontinuous and disperse fibres. One of these cementitious materials is the one usually called by the term GRC. Despite the advances of the GRC technology, this material shows high degradation of its properties throughout the life cycle. Besides that, the fact of being a material which has recently been produced in Brazil on a industrial scale, there is an enormous lack on researches about GRC produced with local materials. Therefore, this research was envisioned with the main objective of evaluating the GRC properties produced with alkali-resistent glass fibres (AR type) and with materials commercially available in Porto Alegre, analyzing its mechanical properties and durability. Specifically, it studied the influence of fibre length (35 mm and 17,5 mm), of silica fume (5%) and metakaolin addition (5%, 10% and 15%), of aggregate/cement relation (1,00 and 1,10) and of the age (28, 42, 49 and 56 days). The measured properties were: proportional limit (PEL), modulus of rupture (MOR), toughness indexes (I5, I10 and I30), modulus of elasticity in bending (MEF), water absorption (ABS), bulk density (MES) and apparent porosity (PAP). In addition, the mechanicals properties of GRC under the effect of ageing (stored in water at 50°C to accelerate the ageing) were investigated where the test were carried out after 14, 21 and 28 days of the accelerated ageing. The results showed that while some properties are mainly influenced by the matrix properties (PEL, MEF, ABS, MES and PAP), others are basically dependent on the fiber reinforcement properties (MOR, I5, I10 and I30). Despite the fact that GRC produced with greater fibre length showed increases at MOR and in energy absorption capacity, it lead to losses of those properties that are mainly influenced by the matrix because it is more difficult to consolidate this GRC. Furthermore, the addition of high contents of metakaolin in composites produced with short fibres leads to MOR and toughness indexes to the higher levels found (gotten with long fibres), keeping the benefic effect of using short fibres at the properties that are basically function of the matrix properties. The MOR, I5, I10 and I30 decreased when the GRC suffer accelerated ageing. The results also showed that the use of pozzolanic additions wasn't able to retain the mechanical properties of GRC throughout time

Fibras de vidro

Materiais de construção

Materiais compositos

GRC

Glass fibre

Fibre reinforced cement

Composites

Quantifying the cracking behaviour of strain hardening cement-based composites

Nieuwoudt, Pieter Daniel

03 1900

Thesis (MScEng)--Stellenbosch University, 2012. / ENGLISH ABSTRACT: Strain Hardening Cement Based Composite (SHCC) is a type of High Performance Fibre Reinforced Cement-based Composite (HPFRCC). SHCC contains randomly distributed short fibres which improve the ductility of the material and can resist the full tensile load at strains up to 5 %. When SHCC is subjected to tensile loading, fine multiple cracking occurs that portrays a pseudo strain hardening effect as a result. The multiple cracking is what sets SHCC aside from conventional Reinforced Concrete (RC). Conventional RC forms one large crack that results in durability problems. The multiple cracks of SHCC typically have an average crack width of less than 80 μm (Adendorff, 2009), resulting in an improved durability compared to conventional RC. The aim of this research project is to quantify the cracking behaviour of SHCC which can be used to quantify the durability of SHCC. The cracking behaviour is described using a statistical distribution model, which represents the crack widths distribution and a mathematical expression that describes the crack pattern. The cracking behaviour was determined by measuring the cracks during quasi-static uni-axial tensile tests. The cracking data was collected with the aid of a non-contact surface strain measuring system, namely the ARAMIS system. An investigation was performed on the crack measuring setup (ARAMIS) to define a crack definition that was used during the determination of the cracking behaviour of SHCC. Several different statistical distributions were considered to describe the distribution of the crack widths of SHCC. A mathematical expression named the Crack Proximity Index (CPI) which represents the distances of the cracks to each other was used to describe the crack pattern of SHCC. The Gamma distribution was found to best represent the crack widths of SHCC. It was observed that different crack patterns can be found at the same tensile strain and that the CPI would differ even though the same crack width distribution was found. A statistical distribution model was therefore found to describe the CPI distribution of SHCC at different tensile strains and it was established that the Log-normal distribution best describes the CPI distribution of SHCC. After the cracking behaviour of SHCC was determined for quasi-static tensile loading, an investigation was performed to compare it to the cracking behaviour under flexural loading. A difference in the crack widths, number of cracks and crack pattern was found between bending and tension. Therefore it was concluded that the cracking behaviour for SHCC is different under flexural loading than in tension. / AFRIKAANSE OPSOMMING: “Strain Hardening Cement-based Composite” (SHCC) is ‘n tipe “High Performance Fibre Reinforced Cement-based Composite” (HPFRCC). SHCC bevat kort vesels wat ewekansig verspreid is, wat die duktiliteit van die material verbeter en dit kan die maksimum trekkrag weerstaan tot en met ‘n vervorming van 5 %. Wanneer SHCC belas word met ‘n trekkrag, vorm verskeie fyn krake wat ‘n sogenaamde vervormingsverharding voorstel. Die verskeie krake onderskei SHCC van normale bewapende beton. Normale bewapende beton vorm een groot kraak met die gevolg dat duursaamheidsprobleme ontstaan. Die gemiddelde kraakwydte van SHCC is minder as 80 μm (Adendorff, 2009) en het dus ‘n beter duursaamheid as normale bewapende beton. Die doel van die navorsingsprojek is om die kraak gedrag van SHCC te kwantifiseer en wat dan gebruik kan word om die duursaamheid van SHCC te kwantifiseer. Die kraak gedrag is beskryf deur ‘n statistiese verspreiding model wat die kraak wydtes se verspreiding voorstel en ‘n wiskundige uitdrukking wat die kraak patroon beskryf. Die kraak gedrag was bepaal deur die krake te meet tydens die semi-statiese een-asige trek toetse. Die kraak data was met behulp van ‘n optiese vervormings toestel, naamlik die ARAMIS, versamel. ‘n Ondersoek is gedoen op die kraak meetings opstelling (ARAMIS), om ‘n kraak definisie te definieer wat gebruik is om die kraak gedrag te bepaal. Daar is gekyk na verskeie statistiese verdelings om die kraak wydtes van SHCC te beskryf. Die kraak patroon van SHCC is beskryf met ‘n wiskundige uitdrukking genoem die “Crack Proximity Index” (CPI) wat die krake se afstande van mekaar voorstel. Dit is bevind dat die Gamma verdeling die kraak wydtes van SHCC die beste beskryf. Daar is waargeneem dat verskillende kraak patrone by dieselfde vervorming verkry kan word en dat die CPI kan verskil al is die kraak wydte verdeling dieselfde. ‘n Statistiese verdelingsmodel is dus gevind om die CPI verdeling van SHCC te beskryf by verskillende vervormings, en daar is vasgestel dat die Log-normaal verdeling die CPI verdeling van SHCC die beste beskryf. Nadat die kraak gedrag van SHCC bepaal is vir semi-statiese trek-belasting, is ‘n ondersoek gedoen waar die trek-kraak gedrag vergelyk is met buig-kraak gedrag. ‘n Verskil in die kraak wydtes, aantal krake en kraak patroon is gevind tussen buiging en trek. Dus is die gevolgtrekking gemaak dat die kraak gedrag van SHCC verskillend is in buiging as in trek.

Dissertations -- Civil engineering

Theses -- Civil engineering

Reinforced concrete -- Cracking

Repair and Retrofit Strategies for Structural Concrete against Thermo-Mechanical Loadings

Guruprasad, Y K

January 2014

Reinforced cement concrete (RCC) structures have become an important aspect in most of the buildings in our society around the world. Most of the multistoried reinforced concrete buildings house important institutions such as hospitals, schools, government establishments, defense establishments, business centers, sports stadiums, super markets and nuclear power plants. The cost of construction of such multistoried RCC structures is very high, and these structures need to be maintained and restored based on their functionality and importance using repair and retrofit strategies when these structures undergo damage. The steps involved in restoring RCC structures that have damages using repair / retrofit measures consists of identifying the source or cause of damage, assessment of the degree or extent of damage that has taken place using nondestructive techniques. Based on the assessment of degree of damage suitable repair / retrofit strategy using the appropriate repair material is applied to achieve the required load carrying capacity or strength. The present work involves assessing the efficacy of carbon fibre reinforced polymer (CFRP) based system applied on pre-damaged structural members to restore the member’s strength and stiffness through experimental investigations and finite element predictions. To validate the macrolevel properties of predamaged concrete micromechanical analysis, microscale studies and analytical investigations have been conducted. Plain and reinforced concrete test specimens: cylinders, square prisms and rectangular prisms having 25MPa and 35MPa cylinder compressive strengths pre-damaged due to mechanical (monotonic and cyclic loading) and thermal loading (exposure to different temperature and time durations) with applications of CFRP repair subjected to compression is investigated to study the behavior and enhancement in the compressive strength and stiffness after application of repair. Non destructive testing of thermally damaged concrete (exposed to different temperature and exposure time) is conducted using ultrasonic pulse velocity and tomography methods to understand the degradation in the strength and stiffness of thermally damaged concrete. The results of the non destructive testing helps in assessing the amount of repair that can be applied. To validate the macro scale behavior of thermally damaged concrete micro scale studies was performed adopting micro indentation, petrography, Raman spectroscopy, scanning electron miscroscopy (SEM) and Electron probe micro analysis (EPMA). During the event of a fire in RC structures which have been retrofitted. The high temperature caused due to fire tends to make the concrete to deteriorate and the repair material to delaminate. Loss of strength/ stiffness in concrete and delamination of the repair material in a retrofitted structural component in a structure causes instability which results in partial collapse or complete collapse of the structure. Thermal insulation of concrete and the repair material (CFRP) using geo-polymer mortar and simwool thermal fibre blanket exposed to high temperature and different exposure time are experimentally investigated. This is to evaluate the effectiveness of the thermal insulation in protecting epoxy based structural repair material(CFRP) from thermal damage and to minimize the delamination of the repair material when exposed to high temperatures. Slender columns when loaded eccentrically fail at a load much lesser than their actual load carrying capacity. In RC buildings where additional floors need to be added, in those situations slender columns which are already eccentrically loaded tend to get damaged or fail due to additional load which act on them. Therefore to restore such columns experimental and finite element investigations on reinforced concrete slender columns having 25MPa cylinder compressive strength subjected to eccentric monotonic compressive loading with applications of CFRP repair is studied to understand the behavior and the enhancement in load carrying capacity after application of repair. Experimental investigations are conducted to study fracture and fatigue properties of thermally damaged concrete geometrically similar notched plain and reinforced concrete beams having 25MPa cylinder compressive strength exposed to different combinations of temperature and durations with application of repair (CFRP). Nonlinear fracture parameters of thermally damaged concrete is computed which help in understanding the fracture behavior of thermally damaged concrete and application of repair. Effectiveness of CFRP repair and failure behaviour of these beams are studied when these thermally damaged notch concrete beams are subjected to monotonic and cyclic (fatigue) loading. Reinforced concrete slender beams when subjected to unexpected loads such as earthquakes get damaged. The increase in load carrying capacity and fatigue life of reinforced concrete slender beams having 25MPa cylinder compressive strength in flexure subjected to monotonic and cyclic loading with applications of CFRP repair is investigated using experimental and finite element investigations. Finite element analysis of concrete specimens pre-damaged due to mechanical (monotonic and cyclic loading) / thermal loading (exposure to different temperature and time durations) with applications of CFRP repair and assessment of amount of repair required is investigated. Analytical (empirical) models are developed to assess the mechanical properties of concrete (elastic moduli, compressive strength and split tensile strength) exposed to different temperatures and time durations. Nonlinear fracture parameters of geometrically similar plain concrete notch beams exposed to different temperature and time durations are determined. Fracture parameters (stress intensity factor) of thermally damaged plain and reinforced concrete notched beams with application of CFRP have been determined. Effect of size and shape of thermally damaged plain concrete compression members with application of CFRP wrap have been studied. Crack mouth opening displacements (CMOD), strains and crack lengths of thermally damaged plain concrete (PC) notched beams using digital image correlation has also been determined.

Thermo-Mechanical Loadings

Structural Concrete

Reinforced Cement Concrete Structures

Concrete - Structural Analysis

Reinforced Concrete

Concrete - Analysis

Carbon Fiber Reinforced Polymer

Concrete - Finite Element Analysis

Plain Concrete

Concrete Structures

Reinforced Cement Concrete (RCC)

CFRP Repair

Cyclic Loading

High Temperature on Concrete

Civil Engineering

The time-dependent cracking behaviour of strain hardening cement-based composite

Adendorff, Christo Johan

12 1900

Thesis (MScEng (Civil Engineering))--University of Stellenbosch, 2009. / ENGLISH ABSTRACT: Strain Hardening Cement-based Composite (SHCC) is part of the High Performance Fibre Reinforced Cement-based Composite (HPFRCC) family and is a relative new concrete composite. This Fibre Reinforced Cement-based Composite (FRCC) contains randomly distributed short fibres and when subjected to a uni-axial tensile load multiple cracking occurs. The multiple cracking generates fine cracks which are normally smaller than 100 μm and achieve a strain capacity of more than 5 %. There are limited publications regarding the research of sustained tensile tests on SHCC and especially the cracking behaviour of SHCC under quasi-static uni-axial as well as sustained tensile loads. The cracking behaviour is described as the average crack width, number of cracks and descriptive statistical properties which could be used to represent the distribution of the multiple fine cracks under uni-axial tension. There are two types of tests that were under consideration to determine the cracking behaviour of SHCC. The first is quasi-static uniaxial tensile tests and the second is sustained tensile tests. The latter was dependant on the uni-axial tensile tests in terms of the sustained load applied. The sustained loads ranged from 40 % to 80 % of the ultimate tensile resistance recorded from the uni-axial tensile tests that correspond with a strain rate of 0.001 /s. Different strain rates were used for the uni-axial tensile tests to determine the effect on the cracking behaviour. The cracking behaviour was determined with the aid of a non-contact optical 3D digital deformation measuring device called ARAMIS. The content of this thesis gives a background study of the cracking behaviour and relevant research performed on SHCC under certain loads as well as some literature about the timedependant effects of a cement-based composite. The functioning of the device called ARAMIS is explained as well as the resulting effects of this device on the preparation of the test specimens. The experimental framework for the uni-axial and sustained tensile tests is discussed. Thereafter, the experimental results of the tests are depicted and discussed. The results shed some light on the basic material properties such as the average ultimate stress and average ultimate strain, Young’s modulus, etc. for the quasi-static tensile tests as well as shrinkage and creep of SHCC. The cracking behaviour such as the average crack width, number of cracks, the variance and skewness of the distribution of the crack widths in the test specimens for the quasi-static uni-axial and sustained tensile tests are depicted and discussed. The cracking behaviour when subjected to uni-axial tensile tests with different strain rates is significantly governed by the formation of new cracks and the average crack width remains small with increase in strain. There is no significant difference for the cracking behaviour found when subjected to different strain rates. However, when SHCC is subjected to a sustained load then the average crack width is dependant on the number of cracks that form over time as well as the load level. The formation of fewer and wider cracks was observed for specimens loaded at average 40 % of the ultimate tensile resistance stress, however at loading percentages of higher than 65 % more cracks developed which resulted in a smaller average crack width. / AFRIKAANSE OPSOMMING: Vervorming Verharding Sement gebaseerde samestelling “Strain Hardening Cement-based Composite” (SHCC) is deel van die familie van “High Performance Fibre Reinforced Cement-based Composite” (HPFRCC) en is ʼn relatiewe nuwe beton samestelling. Hierdie vesel versterkte sement gebaseerde beton bevat willekeurig verspreide kort vesels en veelvoudige klein krake vorm onder monotoniese trekkragte. Hierdie veelvoudige klein krake is minder as 100 μm wyd en lei tot ʼn vervorming van meer as 5 %. Daar is ʼn tekort aan navorsing oor die kruip van SHCC sowel as die kraak gedrag van hierdie sement gebaseerde samestelling onderhewig aan trek. Die kraak gedrag word beskryf as die gemiddelde kraakwydte, aantal krake en ʼn paar beskrywende statistiese parameters. Hierdie kraak gedrag parameters kan gebruik word om ʼn verdeling te kan weergee van die veelvoudige klein krake onder ʼn trek belasting. Twee tipes toetse was uitgevoer om die kraak gedrag te beskryf. Die eerste tipe toets was monotoniese trek toetse en die tweede tipe was kruip toetse. Die tweede toets was afhanklik van die monotoniese trek toetse in terme van die belasting wat gebruik was vir die kruip toetse. Die belasting was gevarieer vanaf 40 % tot 80 % van die breekbelasting wat bepaal is met die monotoniese trektoetse wat ooreenstem met ʼn vervorming tempo van 0.001 /s. Verskillende vervorming tempo’s vir die monotoniese trektoetse was uitgevoer om te bepaal wat die effek is op die kraak gedrag. Die kraak gedrag was bepaal met behulp van ʼn geen-kontak optiese 3D digitale deformasie meet instrument genoem ARAMIS. Die inhoud van die tesis bevat ʼn kort opsoming oor ʼn agtergrond studie van die kraak gedrag en relevante navorsing oor vesel versterkte sement gebaseerde beton, sowel as literatuur oor die tydafhanklike effekte van ʼn sement gebaseerde samestelling. Die beheer en gebruik van die meet instrument ARAMIS word verduidelik, sowel as die effek van hierdie masjien op die voorbereiding vir die eksperimente. Die eksperimentele uiteensetting vir die monotoniese en kruip toetse word beskryf. Daarvolgens is die resultate van die eksperimentele toetse getoon en verduidelik. Die resultate verduidelik die basiese materiaal eienskappe, byvoorbeeld die gemiddelde breekspanning met die ooreenkomstige breekvervorming, Young’s modulus en so voorts vir die monotoniese trektoetse, sowel as eienskappe met betrekking tot krimp en kruip van SHCC. Die kraak gedrag naamlik die gemiddelde kraakwydte, aantal krake per meter, variansie en die skuinsheid van die ontwikkelde krake met die toets proefstukke vir die monotoniese en kruip trek toetse word weergegee en verduidelik. Die kraak gedrag van SHCC wanneer getoets word met verskillende monotoniese trektoets tempo’s word beheer deur die ontwikkeling van nuwe krake en die gemiddelde kraakwydte is beduidend laag met toenemende vervorming. Daar is geen beduidende verskil in die kraak gedrag ten opsigte van die verskillende monotoniese trek tempo’s nie. In teendeel, wanneer SHCC belas word met ʼn konstante las oor tyd word die gemiddelde kraakwydte beheer deur die ontwikkeling van nuwe krake sowel as die belasting wat aangewend is. Onder ʼn belasting van so laag as 40 % van die breekbelasting vorm daar minder krake, maar met ʼn groter gemiddelde kraakwydte. Wanneer belas word met meer as 65 % van die breekbelasting vorm meer krake wat lei tot ʼn kleiner gemiddelde kraakwydte.

Cracking

Time-dependent

Crack widths

Theses -- Civil engineering

Dissertations -- Civil engineering

Strain hardening

Composite-reinforced concrete

Civil Engineering

Thermal Performance of Various Roof Elements Under Different Weather Conditions

Joshi, Vijesh Vasanth

January 2015

Beside the point of whether the country is developed or underdeveloped, energy crisis is a common scene all over the world. In order to balance energy supply and demand, either one has to increase the supply or decrease the demand. The latter seems to be the better choice since we have limited sources of energy. About 20% - 40% of energy produced by a country is being consumed by HVACs in buildings. Hence much e ort is towards energy conservation in buildings. Around 30% of the building energy consumption in India is due to cooling load. Previous studies have shown that around 60% of the heat due to solar radiation enters through the roof of the building. The present work aims to reduce the heat load entering through the roof by coming up with a better roofing technique for moderate climatic regions. In the present work, enclosures with the side walls and the floor (bottom slab) insulated has been studied both numerically and experimentally. Heat transfer between the ambient and enclosure is only through the roof (top slab). Six common roofing types have been studied in this thesis. Reinforced cement concrete (RCC) roof Mangalore tile roof Thatched roof GI Sheet roof and Concrete roof with lawn (green roof) Concrete roof with a layer of wet sand The experimental studies have been carried out to understand heat transfer through these roofs. A comparative study of all six types of roofs has been done. Apart from this, the effect of a shade net on room models with bare RCC roof and GI sheet roof is also studied and presented in this thesis. Each enclosure has a height of 0.3m and the sides are 1m in size. Mangalore tile and thatched roofs are inclined to the horizontal. To understand the heat flow process, the temperature variations of different surfaces and enclosure air, and, air temperatures near the top and bottom slabs were recorded. In addition, weather conditions such as solar radiation, ambient air temperature, and wind speed are recorded. The details of the experimental set up are given in chapter 3. In chapter 2, a mathematical model to determine the temperature variations in the enclosure is given. All the three modes of heat transfer (conduction, convection and radiation) are present and the system is unsteady. The objective is to find the temperatures of the walls and the enclosure air temperature. Heat flows either from surroundings to the enclosure or from enclosure to the surroundings through the walls of the enclosure. As the solar radiation data is known for a given location, un-steady heat conduction equation is solved for the walls of the enclosure with heat flux boundary conditions to solve for the temperatures. Standard correlations have been used for calculating the convective heat transfer to the ambient and in the enclosure. Most importantly, the experiments conducted were field experiments. The main objective of the study had been to understand the effect of roof on thermal comfort conditions inside the scaled model rooms under five different weather conditions which are commonly observed in warm tropics: (1)summer, (2)winter, (3)cloudy, (4)unsteady, and, (5)rainy. The details of weather conditions have been discussed in chapter 4. In the present analysis, various issues were looked upon such as, temperature values, time lag, thermo-physical properties of the roof material, weather conditions, average over a 24 hours cycle etc. For the comparative analysis, bare RCC roof has been assumed to the base case as most of the buildings are built with RCC roof (for example, in India, around 29% of the buildings have RCC roof, as per 2011 census). On one side we have passive cooling techniques (lawn over RCC roof and wet sand over RCC roof), and, on the other side we have breathing roofs (Mangalore tile roof and thatched roof). Apart from these, the GI sheet roof is commonly used for small scale industries and residential houses. It has been observed that the concrete roof with lawn (hereafter called as lawn over RCC roof ) being the best one among the considered six roofs. Having lawn over RCC roof could result reduction in both solar gain and the diurnal variation of enclosure inside temperatures. The range of temperature variation was least disturbed due to change in weather conditions. In the case of wet sand over RCC roof, the diurnal variations of enclosure inside temperatures were relatively higher as compared with those in the lawn over RCC roof case. As far as breathing roofs are concerned, the two were found to be better than bare RCC roof with thermal comfort as point of view. On the other hand, breathing effects are found to be better in case of Mangalore tile roof than in case of thatched roof. GI sheet roof was found to be the worst among considered for thermal comfort. The effect of using shade net over RCC and GI sheet roof proves to have good potential to reduce cooling load with negligible adverse effects during night time. Detailed discussion of results has been done in chapter 4. Numerical simulations have been carried out for the case of model room with bare RCC roof. A comparative analysis of both experimental and numerical results has been discussed in chapter 5. The important conclusions are discussed in chapter 6.

Roofs - Heat Transfer

Roofs - Thermal Performance

Reinforced Cement Concrete (RCC) Roof

Mangalore Tile roof

Thatched Roof

GI Sheet Roof

Concrete Roof with Lawn (Green Roof)

Concrete Roof with a Layer of Wet Sand

Mechanical Engineering

Studies on nonlinear mechanical wave behavior to characterize cement based materials and its durability

Eiras Fernández, Jesús Nuño

10 October 2016

[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 / TESIS / Premios Extraordinarios de tesis doctorales

Nonlinear acoustic

Durability

Cement based materials

Concrete

Concrete durability

Cement-based materials

Durability test

Mortar

Portland cement mortar

Portland cement durability

Resonant inspection techniques

Resonant acoustic

Nonlinear resonance

Nonlinear resonant

Non-classical nonlinear elastic

Nondestructive test

Resonant frequency method

Nonlinear elastic

Resonant frequency

NIRAS

Nonlinear attenuation

Quality factor

Carbonation

Freezing-thawing damage

Frost damage

Glass reinforced cement

Glass reinforced concrete

GRC

Thermal shock

Drying shrinkage

Hysteretic parameter

Nonlinear hysteretic parameter

Nonlinear modulus

Dynamic modulus

Dynamic acousto-elastic test

Structural health monitoring

Nondestructive evaluation

NDE

NDT

DAET

DAET-CW

Continuous wave

Nonlinear wave propagation

INGENIERIA DE LA CONSTRUCCION