Effects of Ground Granulated Blast Furnace Slag in Portland Cement Concrete

Effects of Ground Granulated Blast Furnace Slag in Portland Cement Concrete
Author: Irene K. LaBarca
Publisher:
Total Pages: 98
Release: 2007
Genre: Portland cement
ISBN:

This research examined the properties of concrete containing grade 120 slag cement at replacement levels of 0%, 30%, and 50%. The primary concrete properties studied were compressive strength, split-tensile strength, and deicer scaling resistance. Material variations included four sources of ordinary portland cement and two types of coarse aggregate. Strength properties were studied at room temperature and 40°F mix and curing conditions. Deicer scaling resistance was studied for concrete cured under six curing conditions. Carbonation of concrete cured under these six conditions was also investigated.

Wisconsin Transportation Research, 2000

Wisconsin Transportation Research, 2000
Author: Wisconsin. Department of Transportation
Publisher:
Total Pages: 64
Release: 2001
Genre: Highway planning
ISBN:

This Report to Stakeholders reviews some of our transportation research efforts in Wisconsin during the past four years. A few of these studies are already complete and have made a significant impact on the way we do business. Many of the projects will be finished in the coming months. For all of us interested in Wisconsin's transportation future, the report provides an overview of these diverse and laudable investigations.

Report on Pervious Concrete

Report on Pervious Concrete
Author: ACI Committee 522
Publisher:
Total Pages: 38
Release: 2010
Genre: Lightweight concrete
ISBN: 9780870313646

"This report provides technical information on pervious concrete's application, design methods, materials, properties, mixture proportioning, construction methods, testing, and inspection. The term 'pervious concrete' typically describes a near-zero-slump, open-graded material consisting of portland cement, coarse aggregate, little or no fine aggregate, admixtures, and water." [p. 1]

Ultra-High Performance Concrete and High Performance Building Materials for Sustainable Construction

Ultra-High Performance Concrete and High Performance Building Materials for Sustainable Construction
Author: Ekkehard Fehling
Publisher: BoD – Books on Demand
Total Pages: 310
Release: 2024-01-01
Genre: Technology & Engineering
ISBN: 3737611599

Sustainable construction, with the overarching goal of reducing the environmental footprint of everything we build is becoming increasingly important and urgent in the light of the climate change the world is facing. The use of innovative and sustainable building materials, especially concrete as the worldwide most commonly used building material, offers a great opportunity to significantly reduce climate-relevant emissions in the construction sector. Due to their performance and reliable durability, the use of innovative high-performance concretes will help to reduce the need for new constructions and to sustainably repair existing infrastructure. In new buildings in particular, the use of high-performance materials can help to save energy and natural resources, which reduces climate-relevant emissions and thus global warming. With the current HiPerMat 6, we are responding to the growing understanding of the impact of our construction activities on the environment by placing greater emphasis on sustainability issues.

Recent Advances in Durability Improvement and Low-Carbon Strategy of Engineering Materials and Structures

Recent Advances in Durability Improvement and Low-Carbon Strategy of Engineering Materials and Structures
Author: Zhongya Zhang
Publisher: Frontiers Media SA
Total Pages: 222
Release: 2024-08-28
Genre: Technology & Engineering
ISBN: 2832553672

Global warming, caused by a significant increase in the concentration of greenhouse gases (GHGs) such as CO2, has become a concern all over the world. The whole process carbon emissions of the civil engineering industry account for nearly 40% of global energy and process-related CO2 emissions, more than half of which come from the process of producing, using, constructing and dismantling in civil engineering materials and structures, resulting in the embodied carbon emissions. With the acceleration of global warming, warmer and uncertain climates will make engineering materials and structures subject to more severe environmental conditions. A series of durability issues will occur more frequently, such as the significant variations of humidity in air, the chloride-induced corrosion caused by the severe chloride ingress, concrete cracking caused by the expansion of rusts, and more severe carbonation of concrete structures due to the increase in CO2 concentration. The adoption of positive measures to address climate change has become a global consensus, as global warming has led to serious threats and challenges to the survival and development of humankind.