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Development, application and early-age monitoring of fiber-reinforced ‘crack-free’ cement-based overlaysGupta, Rishi 05 1900 (has links)
In most industrialized countries, significant future activity in the construction sector will be related to repair and rehabilitation of aging infrastructure. This will require use of durable and high performance repair materials. Among various mechanisms cited for lack of durability in repairs, early-age shrinkage cracking in overlay materials is of utmost importance.
Fiber-reinforcement can be used to alleviate some of the issues related to plastic shrinkage. However, quantifying the performance of cement-based composites under restrained shrinkage conditions remains an issue. Various test techniques are available to measure free and restrained shrinkage, but do not simulate the real constraint imposed by the substrate on the overlay.
In this dissertation, an innovative test method called the bonded overlay technique is described. An overlay of fiber-reinforced material to be tested is cast directly on a substrate, and the entire assembly is subjected to controlled drying. Cracking in the overlay is then monitored and characterized. During the development of this test method, instrumentation was included to enable measurement of the crack propagation rate using image analysis, evaporation rate, heat development, and strain using embedded sensors.
Using the above technique, the effect of mix proportion including variables such as water-cement ratio (w/c), sand-cement ratio (s/c), and coarse aggregate content were studied. An increase in w/c from 0.35 to 0.6 significantly increased the total cracking. Addition of coarse aggregates reduced shrinkage cracking, however, for the range of s/c investigated, no definite conclusions could be drawn. Mixes with 0-20% fly ash and a 7 lit/m3 dosage of shrinkage reducing admixtures indicated no significant reduction in cracking.
The influence of fiber geometry on cracking in overlays was also investigated. Fiber types included different sizes of polypropylene and cellulose fibers and one type of glass fiber (volume fraction ranging between 0-0.4%). Glass fibers at a small dosage of 0.1% were the most efficient fiber and completely eliminated cracking.
Of the two field projects considered: one was a plaza deck at the UBC Aquatic Center, where cellulose fibers were used, and the second at the UBC ChemBioE building, where polypropylene fibers were used in slabs-on-grade. Both overlays were instrumented with strain sensors, data from which were monitored over the Internet. Results clearly indicated that fibers reduced the strain development in fiber-reinforced overlays when compared to un-reinforced overlays. An energy-based fracture model was proposed to predict maximum crack widths and in a second study, an equation was proposed to correlate early-age shrinkage and flexural toughness of cellulose fibers. In both models, a reasonable correlation with the test data was observed. In addition, factorial design method was used and a mathematical model was proposed to correlate different variables such as w/c, s/c, and fiber dosage.
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Development, application and early-age monitoring of fiber-reinforced ‘crack-free’ cement-based overlaysGupta, Rishi 05 1900 (has links)
In most industrialized countries, significant future activity in the construction sector will be related to repair and rehabilitation of aging infrastructure. This will require use of durable and high performance repair materials. Among various mechanisms cited for lack of durability in repairs, early-age shrinkage cracking in overlay materials is of utmost importance.
Fiber-reinforcement can be used to alleviate some of the issues related to plastic shrinkage. However, quantifying the performance of cement-based composites under restrained shrinkage conditions remains an issue. Various test techniques are available to measure free and restrained shrinkage, but do not simulate the real constraint imposed by the substrate on the overlay.
In this dissertation, an innovative test method called the bonded overlay technique is described. An overlay of fiber-reinforced material to be tested is cast directly on a substrate, and the entire assembly is subjected to controlled drying. Cracking in the overlay is then monitored and characterized. During the development of this test method, instrumentation was included to enable measurement of the crack propagation rate using image analysis, evaporation rate, heat development, and strain using embedded sensors.
Using the above technique, the effect of mix proportion including variables such as water-cement ratio (w/c), sand-cement ratio (s/c), and coarse aggregate content were studied. An increase in w/c from 0.35 to 0.6 significantly increased the total cracking. Addition of coarse aggregates reduced shrinkage cracking, however, for the range of s/c investigated, no definite conclusions could be drawn. Mixes with 0-20% fly ash and a 7 lit/m3 dosage of shrinkage reducing admixtures indicated no significant reduction in cracking.
The influence of fiber geometry on cracking in overlays was also investigated. Fiber types included different sizes of polypropylene and cellulose fibers and one type of glass fiber (volume fraction ranging between 0-0.4%). Glass fibers at a small dosage of 0.1% were the most efficient fiber and completely eliminated cracking.
Of the two field projects considered: one was a plaza deck at the UBC Aquatic Center, where cellulose fibers were used, and the second at the UBC ChemBioE building, where polypropylene fibers were used in slabs-on-grade. Both overlays were instrumented with strain sensors, data from which were monitored over the Internet. Results clearly indicated that fibers reduced the strain development in fiber-reinforced overlays when compared to un-reinforced overlays. An energy-based fracture model was proposed to predict maximum crack widths and in a second study, an equation was proposed to correlate early-age shrinkage and flexural toughness of cellulose fibers. In both models, a reasonable correlation with the test data was observed. In addition, factorial design method was used and a mathematical model was proposed to correlate different variables such as w/c, s/c, and fiber dosage.
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Development, application and early-age monitoring of fiber-reinforced ‘crack-free’ cement-based overlaysGupta, Rishi 05 1900 (has links)
In most industrialized countries, significant future activity in the construction sector will be related to repair and rehabilitation of aging infrastructure. This will require use of durable and high performance repair materials. Among various mechanisms cited for lack of durability in repairs, early-age shrinkage cracking in overlay materials is of utmost importance.
Fiber-reinforcement can be used to alleviate some of the issues related to plastic shrinkage. However, quantifying the performance of cement-based composites under restrained shrinkage conditions remains an issue. Various test techniques are available to measure free and restrained shrinkage, but do not simulate the real constraint imposed by the substrate on the overlay.
In this dissertation, an innovative test method called the bonded overlay technique is described. An overlay of fiber-reinforced material to be tested is cast directly on a substrate, and the entire assembly is subjected to controlled drying. Cracking in the overlay is then monitored and characterized. During the development of this test method, instrumentation was included to enable measurement of the crack propagation rate using image analysis, evaporation rate, heat development, and strain using embedded sensors.
Using the above technique, the effect of mix proportion including variables such as water-cement ratio (w/c), sand-cement ratio (s/c), and coarse aggregate content were studied. An increase in w/c from 0.35 to 0.6 significantly increased the total cracking. Addition of coarse aggregates reduced shrinkage cracking, however, for the range of s/c investigated, no definite conclusions could be drawn. Mixes with 0-20% fly ash and a 7 lit/m3 dosage of shrinkage reducing admixtures indicated no significant reduction in cracking.
The influence of fiber geometry on cracking in overlays was also investigated. Fiber types included different sizes of polypropylene and cellulose fibers and one type of glass fiber (volume fraction ranging between 0-0.4%). Glass fibers at a small dosage of 0.1% were the most efficient fiber and completely eliminated cracking.
Of the two field projects considered: one was a plaza deck at the UBC Aquatic Center, where cellulose fibers were used, and the second at the UBC ChemBioE building, where polypropylene fibers were used in slabs-on-grade. Both overlays were instrumented with strain sensors, data from which were monitored over the Internet. Results clearly indicated that fibers reduced the strain development in fiber-reinforced overlays when compared to un-reinforced overlays. An energy-based fracture model was proposed to predict maximum crack widths and in a second study, an equation was proposed to correlate early-age shrinkage and flexural toughness of cellulose fibers. In both models, a reasonable correlation with the test data was observed. In addition, factorial design method was used and a mathematical model was proposed to correlate different variables such as w/c, s/c, and fiber dosage. / Applied Science, Faculty of / Civil Engineering, Department of / Graduate
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Introducing New Energy Dissipation Mechanisms for Steel Fiber Reinforcement in Ultra-High Performance ConcreteScott, Dylan Andrew 08 December 2017 (has links)
By adding annealed plain carbon steel fibers and stainless steel fibers into Ultra-High Performance Concrete (UHPC), we have increased UHPC’s toughness through optimized thermal processing and alloy selection of steel fiber reinforcements. Currently, steel fiber reinforcements used in UHPCs are extremely brittle and have limited energy dissipation mainly through debonding due to matrix crumbling with some pullout. Implementing optimized heat treatments and selecting proper alternative alloys can drastically improve the post-yield carrying capacity of UHPCs for static and dynamic applications through plastic deformations, phase transformations, and fiber pullout. By using a phase transformable stainless steel, the ultimate flexural strength increased from 32.0 MPa to 42.5 MPa (33%) and decreased the post-impact or residual projectile velocity measurements an average of 31.5 m/s for 2.54 cm and 5.08 cm thick dynamic impact panels.
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Behaviour of strip footing on fiber-reinforced model slopesMirzababaei, M., Inibong, E., Mohamed, Mostafa H.A., Miraftab, M. January 2014 (has links)
No / Laboratory scale model slopes reinforced with waste carpet fibers were made in a rigid tank with dimensions of 800 mm x 300 mm x 500 mm. Bearing capacities of the strip footing rested on non-reinforced and fiber-reinforced model slopes with 1%, 3% and 5% fiber content were compared at 20% footing displacement ratio. The influence of location of footing on the bearing capacity was studied with placing the footing at different edge distances from the crest of the footing (i.e., 150 mm, 100 mm and 0). Suction probe sensors were installed at appropriate locations on the rear side of the model slope to measure the pore-water pressure generated due to the footing pressure. Results showed that fiber reinforcement increased the bearing resistance of the model slopes significantly. Inclusion of 5% fiber increased the bearing resistance by 271% compared to that of non-reinforced model slope at the footing edge distance ratio of 3. The location of footing was found to affect the load-carrying capacity of the fiber-reinforced model slope. The increase in the edge distance ratio of the footing increased the load-carrying capacity of the model slope.
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Dynamic mechanical properties of cementitious composites with carbon nanotubesWang, J., Dong, S., Ashour, Ashraf, Wang, X., Han, B. 29 October 2019 (has links)
Yes / This paper studied the effect of different types of multi-walled carbon nanotubes (MWCNTs) on the dynamic mechanical properties of cementitious composites. Impact compression test was conducted on various specimens to obtain the dynamic stress-strain curves and dynamic compressive strength as well as deformation of cementitious composites. The dynamic impact toughness and impact dissipation energy were, then, estimated. Furthermore, the microscopic morphology of cementitious composites was identified by using the scanning electron microscope to show the reinforcing mechanisms of MWCNTs on cementitious composites. Experimental results show that all types of MWCNTs can increase the dynamic compressive strength and ultimate strain of the composite, but the dynamic peak strain of the composite presents deviations with the MWCNT incorporation. The composite with thick-short MWCNTs has a 100.8% increase in the impact toughness, and the composite with thin-long MWCNTs presents an increased dissipation energy up to 93.8%. MWCNTs with special structure or coating treatment have higher reinforcing effect to strength of the composite against untreated MWCNTs. The modifying mechanisms of MWCNTs on cementitious composite are mainly attributed to their nucleation and bridging effects, which prevent the micro-crack generation and delay the macro-crack propagation through increasing the energy consumption.
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Determination Of Mechanical Properties Of Hybrid Fiber Reinforced ConcreteYurtseven, Alp Eren 01 August 2004 (has links) (PDF)
ABSTRACT
DETERMINATION OF MECHANICAL PROPERTIES OF
HYBRID FIBER REINFORCED CONCRETE
Yurtseven, Alp Eren
M.Sc. Department of Civil Engineering
Supervisor: Prof. Dr. Mustafa Tokyay
Co-Supervisor: Asst. Prof. Dr. . Ö / zgü / r Yaman
August 2004, 82 pages
Fiber reinforcement is commonly used to provide toughness and ductility to brittle
cementitious matrices. Reinforcement of concrete with a single type of fiber may
improve the desired properties to a limited level. A composite is termed as hybrid, if
two or more types of fibers are rationally combined to produce a composite that
derives benefits from each of the individual fibers and exhibits a synergetic response.
This study aims to characterize and quantify the mechanical properties of hybrid
fiber reinforced concrete. For this purpose nine mixes, one plain control mix and
eight fiber reinforced mixes were prepared. Six of the mixes were reinforced in a
hybrid form. Four different types of fibers were used in combination, two of which
were macro steel fibers, and the other two were micro fibers. Volume percentage of
fiber inclusion was kept constant at 1.5%. In hybrid reinforced mixes volume
percentage of macro fibers was 1.0% whereas the remaining fiber inclusion was
v
composed of micro fibers. Slump test was carried out for each mix in the fresh state.
28-day compressive strength, flexural tensile strength, flexural toughness, and impact
resistance tests were performed in the hardened state. Various numerical analyses
were carried out to quantify the determined mechanical properties and to describe the
effects of fiber inclusion on these mechanical properties.
Keywords: Fiber Reinforcement, Hybrid Composite, Toughness, Impact
Resistance
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Ensaios de placa em areia não saturada reforçada com fibras / Plate load tests on fiber-reinforced unsaturated sandsGirardello, Vinícius January 2010 (has links)
O objetivo do presente trabalho foi estudar o comportamento mecânico de uma areia não saturada, com e sem reforço de fibras, através de ensaios de placa realizados em densidade relativa de 50% e 90%. Para o reforço da areia foi acrescentada a quantidade de 0,5% de fibra de polipropileno em relação ao peso seco de solo. A análise dos resultados dos ensaios de placa indica que a inclusão de fibras influencia significativamente no comportamento carga-recalque do material. O melhor resultado foi obtido para o ensaio realizado na maior densidade relativa (DR = 90%) com adição de fibras, apresentando uma mudança significativa no comportamento carga-recalque. Ensaios triaxiais também foram realizados a fim de obter os parâmetros de resistência e deformação dos materiais estudados. Além disso, ensaios de sucção foram realizados para avaliar a sua influência sobre os parâmetros de resistência do solo não saturado, com e sem reforço. / The aim of present research was to study the mechanical behavior of unreinforced and fiber-reinforced unsaturated sand through plate load tests carried out at relative densities of 50% and 90%. For the reinforced sand, 50 mm long polypropylene fibers were added at a concentration of 0.5% by dry weight. The analysis of the plate test results indicates that the soil load-settlement behavior is significantly influenced by the fiber inclusion. The best performance was obtained for the densest (DR=90%) fiber-sand mixture, where a significant change in the load-settlement behavior was observed. Triaxial tests were also carried out in order to establish the strength and deformation parameters of the materials studied. Furthermore, suction tests were carried out to investigate its potential influence on the strength parameters of the unsaturated fiber-reinforced and unreinforced materials.
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Ensaios de placa em areia não saturada reforçada com fibras / Plate load tests on fiber-reinforced unsaturated sandsGirardello, Vinícius January 2010 (has links)
O objetivo do presente trabalho foi estudar o comportamento mecânico de uma areia não saturada, com e sem reforço de fibras, através de ensaios de placa realizados em densidade relativa de 50% e 90%. Para o reforço da areia foi acrescentada a quantidade de 0,5% de fibra de polipropileno em relação ao peso seco de solo. A análise dos resultados dos ensaios de placa indica que a inclusão de fibras influencia significativamente no comportamento carga-recalque do material. O melhor resultado foi obtido para o ensaio realizado na maior densidade relativa (DR = 90%) com adição de fibras, apresentando uma mudança significativa no comportamento carga-recalque. Ensaios triaxiais também foram realizados a fim de obter os parâmetros de resistência e deformação dos materiais estudados. Além disso, ensaios de sucção foram realizados para avaliar a sua influência sobre os parâmetros de resistência do solo não saturado, com e sem reforço. / The aim of present research was to study the mechanical behavior of unreinforced and fiber-reinforced unsaturated sand through plate load tests carried out at relative densities of 50% and 90%. For the reinforced sand, 50 mm long polypropylene fibers were added at a concentration of 0.5% by dry weight. The analysis of the plate test results indicates that the soil load-settlement behavior is significantly influenced by the fiber inclusion. The best performance was obtained for the densest (DR=90%) fiber-sand mixture, where a significant change in the load-settlement behavior was observed. Triaxial tests were also carried out in order to establish the strength and deformation parameters of the materials studied. Furthermore, suction tests were carried out to investigate its potential influence on the strength parameters of the unsaturated fiber-reinforced and unreinforced materials.
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Ensaios de placa em areia não saturada reforçada com fibras / Plate load tests on fiber-reinforced unsaturated sandsGirardello, Vinícius January 2010 (has links)
O objetivo do presente trabalho foi estudar o comportamento mecânico de uma areia não saturada, com e sem reforço de fibras, através de ensaios de placa realizados em densidade relativa de 50% e 90%. Para o reforço da areia foi acrescentada a quantidade de 0,5% de fibra de polipropileno em relação ao peso seco de solo. A análise dos resultados dos ensaios de placa indica que a inclusão de fibras influencia significativamente no comportamento carga-recalque do material. O melhor resultado foi obtido para o ensaio realizado na maior densidade relativa (DR = 90%) com adição de fibras, apresentando uma mudança significativa no comportamento carga-recalque. Ensaios triaxiais também foram realizados a fim de obter os parâmetros de resistência e deformação dos materiais estudados. Além disso, ensaios de sucção foram realizados para avaliar a sua influência sobre os parâmetros de resistência do solo não saturado, com e sem reforço. / The aim of present research was to study the mechanical behavior of unreinforced and fiber-reinforced unsaturated sand through plate load tests carried out at relative densities of 50% and 90%. For the reinforced sand, 50 mm long polypropylene fibers were added at a concentration of 0.5% by dry weight. The analysis of the plate test results indicates that the soil load-settlement behavior is significantly influenced by the fiber inclusion. The best performance was obtained for the densest (DR=90%) fiber-sand mixture, where a significant change in the load-settlement behavior was observed. Triaxial tests were also carried out in order to establish the strength and deformation parameters of the materials studied. Furthermore, suction tests were carried out to investigate its potential influence on the strength parameters of the unsaturated fiber-reinforced and unreinforced materials.
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