Free and bound chloride contents in cementitious materials

Chloride attack is the main cause of structural damage in reinforced concrete buildings exposed to marine environments. When a certain threshold concentration of chlorides is reached at the concrete-reinforcement interface, the corrosion of the steel rebars is initiated. A part of the intruding chloride ions will be retained by the hydration products of the binder in concrete, either through chemical binding or by physical adsorption. Therefore, chloride binding can delay the achieving of the threshold chloride concentration at the level of the reinforcement by removing chloride ions from the pore solution. Quantifying the chloride binding process helps predict the service-life of reinforced concrete structures exposed to chloride attack, and allows for a better planning of their maintenance and repair periods. Another important purpose of studying chloride binding is the design of new cement mixes that are able to slow down chloride intrusion, thus improving the durability of future marine structures. Since the hydration products of cement are responsible for the chloride binding in concrete, this study will focus on the chloride binding in hardened cement paste. A new reaction model will be used in order to predict the hydration products and their relative amounts in an OPC hardened paste. The final scope is to develop an algorithm in order to evaluate the chloride binding capacity of a given cement paste. Two main chloride binding mechanisms – through physical adsorption and through chemical reactions- were taken into account. The model also estimates the amounts of capillary and gel water, thus permitting the calculation of the maximum amount of free chloride ions in the pore solution

Chloride binding in OPC hydration products

No abstract

Free and bound chloride contents in cementitious materials

Chloride attack is the main cause of structural damage in reinforced concrete buildings exposed to marine environments. When a certain threshold concentration of chlorides is reached at the concrete-reinforcement interface, the corrosion of the steel rebars is initiated. A part of the intruding chloride ions will be retained by the hydration products of the binder in concrete, either through chemical binding or by physical adsorption. Therefore, chloride binding can delay the achieving of the threshold chloride concentration at the level of the reinforcement by removing chloride ions from the pore solution. Quantifying the chloride binding process helps predict the service-life of reinforced concrete structures exposed to chloride attack, and allows for a better planning of their maintenance and repair periods. Another important purpose of studying chloride binding is the design of new cement mixes that are able to slow down chloride intrusion, thus improving the durability of future marine structures. Since the hydration products of cement are responsible for the chloride binding in concrete, this study will focus on the chloride binding in hardened cement paste. A new reaction model will be used in order to predict the hydration products and their relative amounts in an OPC hardened paste. The final scope is to develop an algorithm in order to evaluate the chloride binding capacity of a given cement paste. Two main chloride binding mechanisms – through physical adsorption and through chemical reactions- were taken into account. The model also estimates the amounts of capillary and gel water, thus permitting the calculation of the maximum amount of free chloride ions in the pore solution

Chloride binding in OPC hydration products

No abstract

Investigation on the possibilities for recycling construction and demolition waste in to building materials in Tanzania

The scope of this study is to investigate the quality of C&D waste in Tanzania and the possibilities for reusing, recycling and upcycling this waste in the production of building materials. Even though there is currently no landfill for solid waste disposal in Tanzania, open air dumping sites are used. Dumping C&D waste puts pressure for acquisition for large portions of land in order to accommodate the growing waste generation. Due to population growth and limitation land for waste disposal will put extra pressure on C&D waste management in future. The use of C&D waste for building material production can be a best option not only for waste management but also for providing an alternative building material source. Materials used in this study were concrete/masonry rubble recovered from building construction and demolition sites in Dar es Salaam. Concrete/masonry rubble was crushed to produce aggregates. The results show that the recycled aggregates are mineralogically different from natural aggregates; however, their composition is suitable for use as building materials in Tanzania, e.g. as replacement of aggregates in concrete

Investigation on the possibilities for recycling construction and demolition waste in to building materials in Tanzania

The scope of this study is to investigate the quality of C&D waste in Tanzania and the possibilities for reusing, recycling and upcycling this waste in the production of building materials. Even though there is currently no landfill for solid waste disposal in Tanzania, open air dumping sites are used. Dumping C&D waste puts pressure for acquisition for large portions of land in order to accommodate the growing waste generation. Due to population growth and limitation land for waste disposal will put extra pressure on C&D waste management in future. The use of C&D waste for building material production can be a best option not only for waste management but also for providing an alternative building material source. Materials used in this study were concrete/masonry rubble recovered from building construction and demolition sites in Dar es Salaam. Concrete/masonry rubble was crushed to produce aggregates. The results show that the recycled aggregates are mineralogically different from natural aggregates; however, their composition is suitable for use as building materials in Tanzania, e.g. as replacement of aggregates in concrete