Dosage optimization and bolted connections for UHPFRC ties

Camacho Torregrosa, Esteban Efraím

07 January 2014

Concrete technology has been in changeful evolution since the Roman Empire time. It is remarkable that the technological progress became of higher magnitude from the second part of the XX Century. Advances in the development of new cements, the appearance of the fibers as a reinforcement for structural applications, and specially the grand progress in the field of the water reducing admixtures enabled the emergence of several types of special concretes. One of the lasts is the Ultra High Performance Fiber Reinforced Concrete (UHPFRC), which incorporates advances of the Self-Compacting Concrete (SCC), Fiber-Reinforced Concrete (FRC) and Ultra High Strength Concrete (UHSC) technology. This exclusive material requires a detailed analysis of the components compatibility and a high control of the materials and processes. Mainly patented products have been used for the few structural elements carried out so far today, but the costs makes doubtful the development of many other potential applications. In accordance with the previously explained, a simplification of the UHPFRC components and processes is needed. This becomes the first main goal of this Ph.D. thesis, which emphasizes in the use of local available components and simpler mixing processes. Moreover, the singular properties of this material, between ordinary concrete and steel, allow not only the realization of slenderer structures, but also the viability of new concepts unthinkable with ordinary concrete. In this field is focused the second part of the Ph.D. thesis, which develops a bolted connection system between UHPFRC elements. This research summarizes, first of all, the subfamilies belonging to the HPC-UHPC materials. Afterwards, it is provided a detailed comparison between the dosage and properties of more than a hundred of mixtures proposed by several authors in the last ten years of technology. This becomes a useful tool to recognize correlations between dosages and properties and validate or no preconceived ideas about this material. Based on this state of art analysis was performed the later development of mixtures, on Chapter 4, which analized the effect of use of simpler components and processes on the UHPFRC. The main idea was use local components available in the Spanish market, identifying the combinations that provide the best rheological and mechanical properties. Steam curing use was avoided since a process simplification is intended. Diferent dosages were developed to be adapted to various levels of performance, and always trying to be as economical as possible. The concretes designed were selfcompacting and mainly combined two fiber types (hybrid), as the flexural performance was of greater relevance. The compressive strength obtained varied in the range between 100 and 170 MPa (cube L=100 mm), and the flexural strength between 15 and 45 MPa (prism 100 x 100 x 500 mm). Some of the components introduced are very rarely used in UHPFRC, as limestone coarse aggregate or FC3R, a white active residue from the petrol industry. As a result of the research, some simple and practical tips are provided for designers of UHPFRC dosage. At the end of this chapter, five dosages are characterized as examples of useful concretes for different requirement applications. In a second part, the idea of a bolted joint connection between UHPFRC elements was proposed. The connection system would be especially useful for struts and ties elements, as truss structures. The possible UHPFRC failure modes were introduced and two different types of tests were designed and performed to evaluate the joint capacity. The geometry of the UHPFRC elements was modified in order to correlate it with the failure mode and maximum load reached. Also a linear finite element analysis was performed to analyze the UHPFRC elements connection. This supported the results of the experimental tests to deduce formulations that predict the maximum load for each failure mode. Finally, a real size truss structure was assembled with bolted joints and tested to verify the good structural behavior of these connections. To conclude, some applications designed and developed at the Universitat Politècnica de València with the methods and knowledge acquired on UHPFRC are abstracted. In many of them the material was mixed and poured in a traditional precast concrete company, providing adequate rheological and mechanical results. This showed the viability of simpler UHPFRC technology enabling some of the first applications in Spain with this material. / Camacho Torregrosa, EE. (2013). Dosage optimization and bolted connections for UHPFRC ties [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/34790 / TESIS

Dosage optimization

Compatibility

Precast

Bolted connection

Joint

Applications

INGENIERIA DE LA CONSTRUCCION

Critical Velocity of High-Performance Yarn Transversely Impacted by Different Indenters

Boon Him Lim (6504827)

15 May 2019

Critical velocity is defined as projectile striking velocity that causes instantaneous rupture of the specimen under transverse impact. The main goal of this dissertation was to determine the critical velocities of a Twaron^® 2040 warp yarn impacted by different round indenters. Special attention was placed to develop models to predict the critical velocities when transversely impacted by the indenters. An MTS 810 load frame was utilized to perform quasi-static transverse and uniaxial tension experiments to examine the stress concentration and the constitutive mechanical properties of the yarn which were used as an input to the models. A gas/powder gun was utilized to perform ballistic experiments to evaluate the critical velocities of a Twaron^® 2040 warp yarn impacted by four different type of round projectiles. These projectiles possessed a radius of curvature of 2 μm, 20 μm, 200 μm and 2 mm. The results showed that as the projectile radius of curvature increased, the critical velocity also increased. However, these experimental critical velocities showed a demonstrated reduction as compared to the classical theory. Post-mortem analysis via scanning electron microscopy on the recovered specimens revealed that the fibers failure surfaces changed from shear to fibrillation as the radius of curvature of the projectile increased. To improve the prediction capability, two additional models, Euler-Bernoulli beam and Hertzian contact, were developed to predict the critical velocity. For the Euler–Bernoulli beam model, the critical velocity was obtained by assuming the specimen ruptured instantaneously when the maximum flexural strain reached the ultimate tensile strain of the yarn upon impact. On the other hand, for the Hertzian contact model, the yarn was assumed to fail when the indentation depth was equivalent to the diameter of the yarn. Unlike Smith theory, the Euler-Bernoulli beam model underestimated the critical velocity for all cases. The Hertzian model was capable of predicting the critical velocities of a Twaron^® 2040 yarn transversely impacted by 2 μm and 20 μm round projectiles.

Aerospace Materials

Critical velocity

Smith theory

Projectile nose shape

high-performance fiber

Impact resistance of deflection-hardening fiber reinforced concretes with different mixture parameters

Banyhussan, Q.S., Yildirim, Gurkan, Anil, O., Erdem, R.T., Ashour, Ashraf, Sahmaran, M.

31 January 2019

Yes / The impact behavior of deflection-hardening High Performance Fiber Reinforced Cementitious Concretes (HPFRCs) was evaluated herein. During the preparation of HPFRCs, fiber type and amount, fly ash to Portland cement ratio and aggregate to binder ratio were taken into consideration. HPFRC beams were tested for impact resistance using free-fall drop-weight test. Acceleration, displacement and impact load vs. time graphs were constructed and their relationship to the proposed mixture parameters were evaluated. The paper also aims to present and verify a nonlinear finite element analysis, employing the incremental nonlinear dynamic analysis, concrete damage plasticity model and contact surface between the dropped hammer and test specimen available in ABAQUS. The proposed modelling provides extensive and accurate data on structural behavior, including acceleration, displacement profiles and residual displacement results. Experimental results which are further confirmed by numerical studies show that impact resistance of HPFRC mixtures can be significantly improved by a proper mixture proportioning. In the presence of high amounts of coarse aggregates, fly ash and increased volume of hybrid fibers, impact resistance of fiberless reference specimens can be modified in a way to exhibit relatively smaller displacement results after impact loading without risking the basic mechanical properties and deflection-hardening response with multiple cracking.

Deflection-hardening

Impact

Coarse aggregate

Fly ash

Abaqus

Tepelné vlastnosti vysokohodnotného betonu s vláknovou výztuží / Thermal properties of high performance fibre reinforced concrete

Pecháčková, Kateřina

January 2018

This diploma thesis is focused on the study of the thermal properties of high-performance fiber reinforced concrete HPFRC. The composites are based on a combination of steel and polymeric fibers. Typical properties of these materials include high mechanical strength, water resistence and salt penetration. HPFRCs are mainly used in the construction industry to build tall buildings. The differential transient method was used to study thermophysical variables. The theoretical part of the thesis described the types of concrete, their production, and their properties. Furthermore, thermophysical quantities and methods of their determination (stationary and transient methods, thermal analysis) are defined in the thesis. The aim of the thesis was to determine thermal properties, namely thermal conductivity and specific heat capacity. The results of the thesis can reveal changes in the composition of studied materials as well as critical temperatures for damaging the materials.

Déformations différées des bétons fibrés à ultra hautes performances soumis à un traitement thermique / Time-dependent strains of ultra-high performance fiber-reinforced concrete subjected to a heat treatment

Francisco, Philippe

04 April 2012

Les travaux présentés sont une contribution à l’état des connaissances sur les déformations différées des Bétons Fibrés à Ultra hautes Performances (BFUP) subissant un traitement thermique réalisé à température modérée. Ce type de traitement thermique est appliqué dans des conditions de fabrication usine, juste après la mise en œuvre du béton dans son moule, en vue d’accélérer pendant quelques heures le durcissement d’un produit destiné à se voir appliquer une précontrainte au jeune âge. L’analyse bibliographique souligne l’importance de considérer le type de traitement thermique utilisé comme un des paramètres prépondérants associés à la structuration des hydrates à court, moyen et long terme et à la teneur en eau résiduelle libre des bétons. Les résultats expérimentaux ont permis d’une part de quantifier les déformations différées de BFUP subissant un traitement thermique à température modérée et d’autre part de mettre en corrélation ces déformations avec l’évolution de paramètres matériaux mesurés tels que l’humidité relative interne et le degré d’hydratation. Des modèles analytiques adaptés, s’inspirant de ceux présentés dans l’Eurocode 2, sont proposés pour prévoir les déformations différées des BFUP. En outre, la modélisation et les simulations numériques révèlent qu’il est possible de prédire correctement le comportement de ces BFUP tant sur l’évolution des températures internes que sur l’évolution des déformations différées. La prédiction de l’évolution des propriétés des produits en BFUP en fonction de la nature de l’échauffement appliqué devrait permettre en outre l’optimisation des cadences de production et de l’énergie utilisée pour les traitements thermiques. / The work presented is a contribution for the state of knowledge on the time-dependent strains of Ultra-High Performance Fiber-Reinforced Concrete (UHPFRC) subjected to a heat treatment at a moderate temperature. This type of heat treatment is applied under factory’s conditions, just after the placement of the concrete in its mould, in order to accelerate during a few hours the hardening of an intended product to be seen applying a prestressing to the early age. The bibliographical analysis gives the importance to consider the type of heat treatment used as a significant parameter associated to the hydrates’ structure with short, medium and long term and to the free residual water content of the concretes. The experimental results made it possible on the one hand to quantify the time-dependent strains of UHPFRC subjected to a heat treatment at a moderate temperature and on the other hand to correlate these strains with the evolution of material parameters measured such as the internal relative humidity and the degree of hydration. Adapted analytical models, taking as a starting point those presented in Eurocode 2, are proposed to consider the time-dependent strains of UHPFRC. Moreover, modeling and simulations reveal that it is possible to predict correctly the behavior of these UHPFRC as well on the change of internal temperatures as on the change of the time-dependent strains. The prediction of the evolution of the properties of the UHPFRC products according to the nature of the heating applied should allow moreover the optimization of the production cadences and the energy used for the heat treatments.

BFUP

Traitement thermique

Retrait

Fluage

Déformations différées

Précontraint

UHPFRC

Heat treatment

Srinkage

Creep

Time-dependent strains

Prestressed

Oberflächenmodifizierung von textilem ultrahochmolekularen Polyethylen mittels Dielektrischer Barriereentladung / Surface modification of textile ultra-high-molecular-weight polyethylene via dielectric barrier discharge

Bartusch, Matthias

06 September 2016

Textiles ultrahochmolekulares Polyethylen (UHMWPE) besitzt, aufgrund seiner außerordentlich hohen Molmasse und einem kristallinen Anteil von mehr als 80 %, exzellente spezifische Reißfestigkeiten sowie sehr gute Beständigkeiten gegenüber biologischen, chemischen und physikalischen Einflüssen, wodurch es sich für den Einsatz in Schutztextilien, als textiler Träger für funktionelle Partikel, zur Faserverstärkung in Kunststoffen für hochbelastbare Bauteile und auch zur Herstellung hochwertiger, technischer Textilmembranen anbietet. Voraussetzung für diese Applikationen ist ein hohes Wechselwirkungsvermögen der Fasergrenzflächen. Im Rahmen dieser Dissertationsschrift wurden systematisch die Möglichkeiten zur Oberflächenaktivierung von textilem UHMWPE mittels Atmosphärendruckplasma (ADP) untersucht und Eigenschafts-Wirkungsbeziehungen verschiedener Einflussparameter, u. a. Plasmaleistung, Elektrodenabstand, Behandlungsintensität, aufgeklärt. Dabei lag ein besonderes Augenmerk auf den textilen Eigenheiten des Materials und der dadurch stark beeinflussten Durchdringung des Plasmas. Entsprechend wurden umfangreiche Messreihen zu chemischen und physikalischen Veränderungen der Faseroberfläche erstellt, um schließlich eine industrielle Nutzbarkeit der ADP-Behandlung ableiten zu können. Hierzu wurden auch zwei weitere Verfahren vergleichend begutachtet und in Kooperation mit dem Leibniz-Institut für Polymerforschung Dresden e.V. eine mögliche Anwendung aktivierter UMHWPE-Garne als Träger für magnetisierbare Nanopartikel betrachtet.

Polyethylen

UHMW PE

Hochleistungsfaser

Textil

Atmosphärendruckplasma

Dielektrische Barrierentladung

DBD

Plasma

Oberflächemodifikation

polyethylene

UHMW PE

high-performance fiber

textile

atmospheric pressure plasma

dielectric barrier discharge

DBD

plasma

surface modification

ddc:540

rvk:VK 8007

Faser

Atmosphärendruckplasma

Polyethylene

Modifizierung

Oberfläche

Lateral stability of ultra-high performance fiber-reinforced concrete beams with emphasis in transitory phases / Instabilidade lateral de vigas de concreto de ultra-alto desempenho reforçado com fibras com ênfase em fases transitórias

Krahl, Pablo Augusto

04 July 2018

The development of advanced fiber reinforced cement-based materials to provide higher strength, ductility, and durability, as ultra-high performance fiber-reinforced concrete (UHPFRC), enables the design of precast beams with thin sections and reduced self-weight to meet the required flexural performance. However, such slender elements when subjected to transitory phases, and possibly also in permanent stages, are prone to instability failure. So, the present study aims to provide experimental data and analytical solution for UHPFRC beams during the lifting phase, and studies about the other stages. This type of test is rare and was not reported for UHPFRC beams. For testing, the beams were lifted by inclined cables and subjected to a transversal load applied at midspan to induce lateral instability. The displacements of the beams were monitored with total station equipment. Also, a new analytical solution was proposed to predict the failure load of lifted beams and closed-form analytical solutions to predict the rollover load of beams supported by bearing pads and subjected to different loading conditions. Furthermore, there are limited data that characterizes the constitutive behavior of this material. In this context, the present research also focused on providing such laboratory results for UHPFRC with different fiber contents. Besides, analytical models for damage evolution and stress-strain relationship are proposed and applied in numerical simulations. From the results, the UHPFRC beams failed by instability with a load capacity 3.7 times smaller than the flexural load capacity. Furthermore, the analytical solution for lifting predicted the peak load of the experiment with great accuracy. Also, the proposed equations for beams on bearing pads accurately predicted the experimental results available in the literature. The analytical and experimental rollover loads differed by 4.37% and 13.6% for the two studied cases. From material, the stiffness degradation occurred rapidly in UHPFRC under tensile loading while occurred gradually in compression. Also, fiber content influenced toughness and degradation evolution significantly over the loading cycles. Proposed equations were utilized in the Plastic-Damage model of Abaqus that predicted accurately damage growth and cyclic envelopes during all the phases of the tension, compression, and bending tests. The calibrated numerical model also predicted the experimental results with the UHPFRC beams. / O desenvolvimento de materiais avançados à base de cimento reforçado com fibra para fornecer maior resistência, ductilidade e durabilidade, como o concreto de ultra-alto desempenho reforçado com fibras (UHPFRC), permite o projeto de vigas pré-moldadas com seções esbeltas e peso próprio reduzido que atendem desempenho estrutural requerido. No entanto, esses elementos delgados quando submetidos a fases transitórias e também em serviço são propensos a falhar por instabilidade. Então, o presente estudo tem por objetivo apresentar resultados experimentais e soluções analíticas para vigas de UHPFRC durante a fase de içamento e estudos sobre as outras fases. Este tipo de teste é raro e não foi reportado para vigas de UHPFRC. Para o teste, as vigas foram levantadas por cabos inclinados e submetidas a uma carga concentrada transversal aplicada no meio do vão para induzir a instabilidade lateral. Os deslocamentos das vigas foram monitorados com estação total. Além disso, uma nova solução analítica foi proposta para prever a carga de instabilidade das vigas içadas e soluções analíticas para prever a carga de tombamento de vigas suportadas por aparelho de apoio e submetidas a diferentes condições de carregamento. Além disso, existem poucos resultados experimentais que caracterizam o comportamento constitutivo deste material. Neste contexto, a presente pesquisa também se concentrou em fornecer tais resultados experimentais para UHPFRC com diferentes teores de fibras. Além disso, modelos analíticos para evolução de dano e relação tensão-deformação são propostos e aplicados em simulações numéricas. A partir dos resultados, as vigas em içamento falharam por instabilidade com uma capacidade de carga 3,7 vezes menor que a capacidade à flexão. Além disso, a solução analítica para içamento previu carga máxima do experimento com grande precisão. As equações propostas para vigas sobre aparelhos de apoio previram com precisão os resultados experimentais disponíveis na literatura. As cargas de tombamento analíticas e experimental diferiram em 4,37% e 13,6% para os dois casos estudados. Dos resultados do material, a degradação da rigidez ocorreu de maneira rápida no UHPFRC submetido à tração enquanto ocorreu gradualmente na compressão. O teor de fibras influenciou significativamente a tenacidade e a degradação nos ciclos de carregamento. As equações propostas foram utilizadas em um modelo de Dano acoplado à plasticidade que previu com precisão a evolução do dano e as envoltórias cíclicas durante todas as fases dos testes de tração, compressão e flexão. O modelo numérico calibrado também previu os resultados experimentais das vigas de UHPFRC.

Concreto de ultra alto desempenho

CUAD

Damage evolution laws

Instabilidade lateral de vigas

Lateral instability of beams

Leis de evolução de dano

Relação tensão-deformação

Stress-strain relations

UHPC

Lateral stability of ultra-high performance fiber-reinforced concrete beams with emphasis in transitory phases / Instabilidade lateral de vigas de concreto de ultra-alto desempenho reforçado com fibras com ênfase em fases transitórias

Pablo Augusto Krahl

04 July 2018

The development of advanced fiber reinforced cement-based materials to provide higher strength, ductility, and durability, as ultra-high performance fiber-reinforced concrete (UHPFRC), enables the design of precast beams with thin sections and reduced self-weight to meet the required flexural performance. However, such slender elements when subjected to transitory phases, and possibly also in permanent stages, are prone to instability failure. So, the present study aims to provide experimental data and analytical solution for UHPFRC beams during the lifting phase, and studies about the other stages. This type of test is rare and was not reported for UHPFRC beams. For testing, the beams were lifted by inclined cables and subjected to a transversal load applied at midspan to induce lateral instability. The displacements of the beams were monitored with total station equipment. Also, a new analytical solution was proposed to predict the failure load of lifted beams and closed-form analytical solutions to predict the rollover load of beams supported by bearing pads and subjected to different loading conditions. Furthermore, there are limited data that characterizes the constitutive behavior of this material. In this context, the present research also focused on providing such laboratory results for UHPFRC with different fiber contents. Besides, analytical models for damage evolution and stress-strain relationship are proposed and applied in numerical simulations. From the results, the UHPFRC beams failed by instability with a load capacity 3.7 times smaller than the flexural load capacity. Furthermore, the analytical solution for lifting predicted the peak load of the experiment with great accuracy. Also, the proposed equations for beams on bearing pads accurately predicted the experimental results available in the literature. The analytical and experimental rollover loads differed by 4.37% and 13.6% for the two studied cases. From material, the stiffness degradation occurred rapidly in UHPFRC under tensile loading while occurred gradually in compression. Also, fiber content influenced toughness and degradation evolution significantly over the loading cycles. Proposed equations were utilized in the Plastic-Damage model of Abaqus that predicted accurately damage growth and cyclic envelopes during all the phases of the tension, compression, and bending tests. The calibrated numerical model also predicted the experimental results with the UHPFRC beams. / O desenvolvimento de materiais avançados à base de cimento reforçado com fibra para fornecer maior resistência, ductilidade e durabilidade, como o concreto de ultra-alto desempenho reforçado com fibras (UHPFRC), permite o projeto de vigas pré-moldadas com seções esbeltas e peso próprio reduzido que atendem desempenho estrutural requerido. No entanto, esses elementos delgados quando submetidos a fases transitórias e também em serviço são propensos a falhar por instabilidade. Então, o presente estudo tem por objetivo apresentar resultados experimentais e soluções analíticas para vigas de UHPFRC durante a fase de içamento e estudos sobre as outras fases. Este tipo de teste é raro e não foi reportado para vigas de UHPFRC. Para o teste, as vigas foram levantadas por cabos inclinados e submetidas a uma carga concentrada transversal aplicada no meio do vão para induzir a instabilidade lateral. Os deslocamentos das vigas foram monitorados com estação total. Além disso, uma nova solução analítica foi proposta para prever a carga de instabilidade das vigas içadas e soluções analíticas para prever a carga de tombamento de vigas suportadas por aparelho de apoio e submetidas a diferentes condições de carregamento. Além disso, existem poucos resultados experimentais que caracterizam o comportamento constitutivo deste material. Neste contexto, a presente pesquisa também se concentrou em fornecer tais resultados experimentais para UHPFRC com diferentes teores de fibras. Além disso, modelos analíticos para evolução de dano e relação tensão-deformação são propostos e aplicados em simulações numéricas. A partir dos resultados, as vigas em içamento falharam por instabilidade com uma capacidade de carga 3,7 vezes menor que a capacidade à flexão. Além disso, a solução analítica para içamento previu carga máxima do experimento com grande precisão. As equações propostas para vigas sobre aparelhos de apoio previram com precisão os resultados experimentais disponíveis na literatura. As cargas de tombamento analíticas e experimental diferiram em 4,37% e 13,6% para os dois casos estudados. Dos resultados do material, a degradação da rigidez ocorreu de maneira rápida no UHPFRC submetido à tração enquanto ocorreu gradualmente na compressão. O teor de fibras influenciou significativamente a tenacidade e a degradação nos ciclos de carregamento. As equações propostas foram utilizadas em um modelo de Dano acoplado à plasticidade que previu com precisão a evolução do dano e as envoltórias cíclicas durante todas as fases dos testes de tração, compressão e flexão. O modelo numérico calibrado também previu os resultados experimentais das vigas de UHPFRC.

Concreto de ultra alto desempenho

CUAD

Instabilidade lateral de vigas

Leis de evolução de dano

Relação tensão-deformação

Damage evolution laws

Lateral instability of beams

Stress-strain relations

UHPC

Développement de bétons fibrés ultra performants pour la réalisation d'éléments de structure préfabriqués / Development of ultra high performance fibers reinforced concretes for the realization of structural precast elements

Nguyen Phuong Amanjean, Elsa

01 December 2015

Les Bétons Fibrés Ultra Performants (BFUP) sont les matériaux cimentaires aux performances les plus exceptionnelles. Ils se distinguent par des résistances caractéristiques à 28 jours en compression et en traction supérieures respectivement à 150 MPa et 6 MPa. Dans une politique globale de gestion économique et d'impact écologique de l'entreprise Lagarrigue, l'utilisation de BFUP en substitution des bétons de classe de résistance ordinaire en préfabrication parait pertinente. Cependant, les formulations actuelles onéreuses et peu écologiques limitent leur utilisation et leur essor. Cette étude a pour but de proposer des formulations de BFUP industrialisables caractérisées par un meilleur bilan économique et écologique, et conformes aux exigences de la prénorme matériaux BFUP (PR NF P18-470). Suite à une première étude de formulation et d'optimisation, quatre compositions de BFUP ont été mises au point sans traitement thermique, trois à base de métakaolin et une de référence plus classique avec fumée de silice. Leur caractérisation à l'état frais et à l'état durci a ensuite été réalisée afin de dresser leurs cartes d'identité et de les situer de manière réglementaire selon la prénorme (PR NF P18-470). Les bétons formulés sont autoplaçants et thixotropes. Le caractère thixotrope pouvant causer une discontinuité de l'interface entre deux couches de béton lors du coulage, des recommandations vis-à-vis du phasage de fabrication et de bétonnage ont été proposées. A l'état durci, un BFUP avec métakaolin et celui équivalent avec fumée de silice atteignent des résistances en compression supérieures à 150 MPa permettant de les classer en BFUP-S utilisables pour les structures alors que les deux autres formules à base de métakaolin dépassant les 130 MPa sont classés en BFUP-Z non structuraux (PR NF P18-470). En traction, trois BFUP sont de classe T2, leurs résistances élastiques et de post-fissuration sont respectivement comprises entre 6,0 et 8,0 MPa, et entre 4,6 et 7,0 MPa, une dernière composition étant à la limite de classification avec une résistance élastique et post-fissuration de 5,9 et 4,0 MPa respectivement. Les valeurs limites de retrait et du coefficient de fluage de la prénorme (PR NF P18-470) sont respectées. L'étude de la microstructure a permis de conforter certaines hypothèses émises lors de la caractérisation mécanique, notamment le retrait et le fluage. L'étude des propriétés de transfert montre une durabilité potentielle très élevée. La dernière phase constitue un aboutissement de ce projet avec la première application industrielle, basée sur le dimensionnement selon la future norme de calcul BFUP (PR-NF P18-710), qui concerne la réalisation d'éléments préfabriqués d'un ouvrage. / Ultra-High Performance Fiber-Reinforced Concretes are cementitious materials of exceptional performances. They are characterized by a compressive and tensile strength over respectively 150 MPa and 6 MPa at 28 days. Within a global management of economic and the environmental impact of Lagarrigue company, the use of UHPFRC in substitution of ordinary concrete in precast elements seems relevant. However, expensive materials and environmental cost of current mix design restrict their use and development. This study aims at proposing UHPFRC mix designs which are characterized by better economic and environmental cost and respect criteria of the pre-standard UHPFRC materials (PR NF P18-470). Firstly, an optimization study of UHPFRC mix design has been established, four mixtures have been developed without heat treatment application, three of them based on metakaolin and one with silica fume as a reference mixture. Secondly, the characterization of fresh and hardened state was conducted in order to establish their identity cards and confront them to the criteria of (PR NF P18-470. In the fresh state, all concretes studied are self-compacting concretes and present thixotropic character. The thixotropic character may cause a discontinuity of the interface between two layers of concrete during casting, recommendations of manufacturing and casting process have been proposed. In the hardened state, one UHPFRC with metakaolin and another one with silica fume reached compressive strengths over 150 MPa, they could be classified as UHPFRC-S and could be used for structures designs while the two other mixtures based on metakaolin exceeded 130 MPa were classified as non-structural UHPFRC-Z (PR NF P18-470). For tensile behavior, three UHPFRC are classed T2, their elastic and post-cracking strengths are between 6.0 and 8.0 MPa, and between 4.6 and 7.0 MPa respectively, while the last mixture is in the classification limit with elastic and post-cracking strengths of 5.9 and 4.0 MPa respectively. The limit values of shrinkage and creep coefficient recommended (PR NF P18-470) were satisfying. The microstructure evaluation allowed strengthening certain assumptions made in the mechanical characterization, including shrinkage and creep. The durability characterization showed very high potential sustainability materials. The last part is an outcome of this research project with the first industrial application, based on the structural design of the UHPFRC future standard (PR NF-P18-710) which concerns the realization of precast elements of a structure.

Bétons fibrés ultra performants

Formulation

Comportement à l'état frais

Comportement mécanique

Microstructure

Propriétés de transfert

Dimensionnement

Mix design

Fresh behavior

Hardened behavior

Microstructure

Durability

Structural design

Development of a Lightweight Hurricane-Resistant Roof System

Amir Sayyafi, Ehssan

30 March 2017

Roofs are the most vulnerable part of the building envelope that often get damaged when subjected to hurricane winds. Damage to the roofs has a devastating impact on the entire structure, including interior losses and service interruptions. This study aimed at the development of a novel light-weight composite flat roof system for industrial, commercial and multi-story residential buildings to withstand Category 5 hurricane wind effects based on the Florida Building Code requirements for hurricane-prone regions, the strictest wind design code in the United States. The proposed roof system is designed as a combination of two advanced materials: ultra-high performance concrete (UHPC), reinforced with high strength steel (HSS). The novel combination of these two materials in a specially designed cross section led to a lightweight low-profile ultra-thin-walled composite roof deck, with only 17 pounds per square foot self-weight, 4-inch overall depth and only ¾-inch thick flanges and webs, with no shear reinforcement or stirrup. Two groups of specimens, single-cell and multi-cell, were fabricated and tested in four-point flexure to determine the ultimate bending capacity and ductility of the system. Each group of specimens included two short-span (9 ft.) samples (due to the laboratory constraints) -- one specimen subjected to positive bending and the other one subjected to negative bending, representing the critical loading conditions including the effects of wind pressures. All specimens exhibited pure flexural failure in a ductile behavior and with no sign of shear failure. Finite element models of laboratory specimens were also developed and calibrated based on experimental data in order to project the performance of the system for larger and more realistic spans. The experimental work and the finite element analyses showed that the proposed roof system with its given section has adequate flexural and shear strength, and also meets serviceability requirements for a 20-foot long span. Moreover, connections for the roof system were proposed, including panel-to-panel connections and roof-to-wall connections. In addition to safety, the other advantages of the proposed roof system in comparison to the equivalent reinforced concrete roofs include a three-fold reduction in self-weight, a three-fold reduction in overall profile height, and a five-fold reduction of steel reinforcement. Together, these advantages may lead to an increased span length beyond what is typically feasible for the conventional reinforced concrete slabs. All these features translate the proposed deck to a sustainable roof system.

Ultra-High Performance Concrete (UHPC)

Concrete

Deck

High Strength Steel (HSS)

Roof

Wind

Hurricane

Thin-wall

Lightweight

Sustainability

Civil and Environmental Engineering

Civil Engineering

Engineering