Effect Of Elevated Curing Temperature On The Chloride Permeability Of High Strength Lightweight Concrete
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| Author | : OE. Gjørv |
| Publisher | : |
| Total Pages | : 6 |
| Release | : 1994 |
| Genre | : Chloride permeability |
| ISBN | : |
Due to high cement contents and reduced heat capacity, high-strength lightweight concrete is often exposed to elevated curing temperatures. In the production of lightweight concrete the aggregate is often wetted before use, but sometimes dry aggregate is also applied. In order to find out whether elevated curing temperatures in combination with varying moisture conditions of the aggregate would affect the concrete permeability, an experimental investigation was carried out. The results showed that maximum curing temperatures of up to 80°C did not adversely affect the compressive strength when dry aggregate was used, while a temperature above 50°C reduced the compressive strength when wet aggregate was employed. Temperatures above 65°C increased the permeability in both cases of aggregate moisture condition. At 20°C the compressive strength was higher for the wet aggregate concrete (103.8 MPa) compared to that of the dry aggregate concrete (95.3 MPa), but the permeability was also higher for the wet aggregate concrete (150%). When all the moisture was removed at 105°C, the wet aggregate concrete absorbed approximately 15% more water by capillary absorption than the dry aggregate concrete. Backscattered electron images showed a very dense transition zone between cement paste and aggregate both for the dry and the wet aggregate concrete.
| Author | : Hamdi Celik Ozyildirim |
| Publisher | : |
| Total Pages | : 32 |
| Release | : 1998 |
| Genre | : Concrete |
| ISBN | : |
This study evaluated the effects of temperature on the strength and permeability of concretes containing pozzolans (fly ash and silica fume) and slag. Two test programs were conducted. In the first, one control and five experimental mixtures containing silica fume, fly ash, or slag were evaluated. In the second, one control and three experimental mixtures containing fly ash or slag at a higher water-cementitious material ratio (W/CM) than used in the first program were evaluated. Concretes cured at higher temperatures had higher strengths up to 28 days but lower strengths at 1 year. Permeability decreased with time. Increasing early curing temperatures enabled the achievement of lower long-term permeability for 6 months and beyond at 28 days. Concretes containing a pozzolan or slag had a lower long-term permeability than the control. Adding a pozzolan was more effective in reducing permeability than reducing the W/CM. At cold temperatures, if the specified properties are not achieved, the contractor should change the mix design and/or provide insulating blankets and/or external heat to ensure the desired product.
| Author | : Melissa Prevey Titherington |
| Publisher | : |
| Total Pages | : |
| Release | : 1998 |
| Genre | : |
| ISBN | : |
Steam curing is often used in the production of precast concrete. The elevated temperature of steam curing increases the initial rate of strength development allowing for earlier removal of the formwork. Although elevated curing temperatures result in high early strength, long-term strength and durability may be adversely affected. In this study, the chloride penetration resistance of steam-cured concretes containing silica fume alone or in combination with slag was investigated. The water to cement ratio was kept constant, at 0.3, for all concretes. Testing included: (1) Compressive Strength, (2) Rapid Chloride Permeability, (3) Water Sorptivity, (4) Bulk Diffusion, and (5) Chloride Migration. For a given mixture, steam curing was found to decrease chloride resistance. However, the use of supplementary cementing materials significantly reduced the negative effects of steam curing. The performance of a 4% silica fume steam-cured concrete was comparable to that of a 100% OPC ambient-cured concrete.
| Author | : Ole Mejlhede Jensen |
| Publisher | : RILEM Publications |
| Total Pages | : 166 |
| Release | : 2007 |
| Genre | : Concrete |
| ISBN | : 2351580095 |
| Author | : K. Sakai |
| Publisher | : CRC Press |
| Total Pages | : |
| Release | : 2014-04-21 |
| Genre | : Architecture |
| ISBN | : 1482294982 |
The two themes of integration of structural and durability design, and integration of concrete technologies in relation to global environmental issues are drawn together in this book. It presents the views of distinguished international researchers and engineers on these key topics as the 21st century approaches. Derived from a workshop on rational
| Author | : Christopher Michael Evans |
| Publisher | : |
| Total Pages | : 0 |
| Release | : 1997 |
| Genre | : |
| ISBN | : |
Early-stage curing temperature has a significant effect on high performance concrete durability and strength. Concrete cures at high temperatures when poured in large volumes due to the autogeneous heat generated by the hydration reactions of cementitious materials. The addition of supplementary cementing materials to concrete reduces the heat of hydration and extends the service life in structures by improving both long term durability and strength. This thesis investigates the effects of early-age curing temperature on the durability and strength of silica fume and fly ash modified concretes. Accelerated test methods were used to measure chloride diffusion in concretes produced with silica fume cement (T10SF) and various levels and types of fly ash replacement. The concrete mix determined to be the most durable with respect to chloride diffusion had 56% of the Type 10SF cement replaced with a moderate-level calcium content fly ash. The use of the Rapid Chloride Permeability Test, (ASTM C 1202, AASHTO T 277) has been widely criticised. Despite a limited data set, good correlation was shown in the results of this research between a two-chamber accelerated chloride migration cell test, and the RCPT.
| Author | : Stephen Okurut Ekolu |
| Publisher | : |
| Total Pages | : 434 |
| Release | : 2004 |
| Genre | : Concrete |
| ISBN | : |
Phase One investigation was conducted to determine the effect of high-temperature curing on the physical properties of concrete. Portland cement pastes of 0.35 and 0.45 water-cement ratios, and ternary cement (5% silica fume, 25% slag) concretes of 0.35 water-cementitious ratio were cured at 23, 65, 80, and 95°C. The properties examined were the compressive strength, chloride permeability, bulk diffusion, salt scaling, rebar corrosion, pore structure, and microstructure. Results showed that there were drastic changes in concrete properties as the curing temperatures increased above 65°C. This has been termed the 'critical temperature effect'. Salt scaling of concretes was highly sensitive to elevated curing temperatures but the w/c was found to be more influential. Most adverse effects of heat curing were significantly mitigated by using ternary cement concrete except in the case of compressive strength.--Phase Two investigation examined the influence of other deterioration processes on the potential for DEF. The effects of lithium admixtures, alkali-silica reaction and freeze-thaw microcracks, and chloride ingress were investigated using concretes of 0.45 w/c and mortars of o.47 w/c heat cured at 95°C. Studies included X-ray diffraction and differential thermal analysis. It was found that the use of lithium admixture in cementitious systems controls DEF. Also, externally applied chlorides have a pessimum effect on expansion due to DEF. This deviates from the commonly held view that chlorides mitigate sulphate attack in concretes. A mechanism describing the pessimum effect of chlorides on DEF expansion has been proposed.
| Author | : Stephen Okurut Ekolu |
| Publisher | : Library and Archives Canada = Bibliothèque et Archives Canada |
| Total Pages | : 434 |
| Release | : 2004 |
| Genre | : Concrete |
| ISBN | : |
Phase One investigation was conducted to determine the effect of high-temperature curing on the physical properties of concrete. Portland cement pastes of 0.35 and 0.45 water-cement ratios, and ternary cement (5% silica fume, 25% slag) concretes of 0.35 water-cementitious ratio were cured at 23, 65, 80, and 95°C. The properties examined were the compressive strength, chloride permeability, bulk diffusion, salt scaling, rebar corrosion, pore structure, and microstructure. Results showed that there were drastic changes in concrete properties as the curing temperatures increased above 65°C. This has been termed the 'critical temperature effect'. Salt scaling of concretes was highly sensitive to elevated curing temperatures but the w/c was found to be more influential. Most adverse effects of heat curing were significantly mitigated by using ternary cement concrete except in the case of compressive strength.--Phase Two investigation examined the influence of other deterioration processes on the potential for DEF. The effects of lithium admixtures, alkali-silica reaction and freeze-thaw microcracks, and chloride ingress were investigated using concretes of 0.45 w/c and mortars of o.47 w/c heat cured at 95°C. Studies included X-ray diffraction and differential thermal analysis. It was found that the use of lithium admixture in cementitious systems controls DEF. Also, externally applied chlorides have a pessimum effect on expansion due to DEF. This deviates from the commonly held view that chlorides mitigate sulphate attack in concretes. A mechanism describing the pessimum effect of chlorides on DEF expansion has been proposed.
| Author | : American Society for Testing and Materials |
| Publisher | : |
| Total Pages | : 630 |
| Release | : 1994 |
| Genre | : Aggregates (Building materials) |
| ISBN | : |
| Author | : David Campbell Wallace |
| Publisher | : |
| Total Pages | : 56 |
| Release | : 1941 |
| Genre | : |
| ISBN | : |
