Performance Based Specifications for Durability of Mass Concrete Blocks Subjected to Harsh Arabian Gulf Marine Environment

K. Rahman Muhammad; Al Omran Zaki; Ibrahim Mohammed; Al Nahdi Fahad; S. Barry Mohammed

doi:10.4028/www.scientific.net/KEM.711.444

Paper Titles

UHPC and FRC in Severe Environmental Conditions
p.412

High Absorptive Normal Weight Aggregates Used as Internal Curing Agents to Reduce Hot Weather Concreting and Curing Detrimental Effects
p.420

Durability of Ordinary Concrete after Heating at High Temperature
p.428

Experimental Study on Chloride Diffusion, Strength and Fresh Properties of Ion-Exchange Resin Mixed Grout
p.436

Performance Based Specifications for Durability of Mass Concrete Blocks Subjected to Harsh Arabian Gulf Marine Environment
p.444

Mechanical Behavior and Recovery of FRC after High Temperature Exposure
p.457

Combined Effects on Residual Strength of a High Performance Concrete Exposed to Fire
p.465

Effects of Mix Proportion on the Strength and Elasticity of Concrete Subjected to High Temperatures up to 800C
p.472

Fibre Cocktail to Improve Fire Resistance
p.480

HomeKey Engineering MaterialsKey Engineering Materials Vol. 711Performance Based Specifications for Durability of...

Performance Based Specifications for Durability of Mass Concrete Blocks Subjected to Harsh Arabian Gulf Marine Environment

Abstract:

Concrete structures in the Eastern region of Saudi Arabia are exposed to the harsh Arabian Gulf environment, and they suffer from deterioration due to accelerated corrosion of the reinforcing steel resulting in reduced service life. The service life of reinforced concrete structures in this environment is strongly affected by the quality of concrete. The resistances of concrete to chloride penetration, the chloride threshold for corrosion initiation and corrosion rate of the reinforcing steel are critical in ensuring long-term durability of concrete structures. In order to ensure that the concrete functions in the harsh environment for which it is expected to meet the service life requirement, the concrete must be designed for durability performance. A prescriptive concrete specification emphasizing on limits on mix parameters is generally ineffective for durability issues. A performance based specification based on concrete quality represented by durability indices and compliance criteria measured on cast-in-place concrete provides a framework for the contractor and ready-mix concrete supplier to produce a structure meeting the stipulated service life by the client. This paper presents the results of experimental investigations conducted for mass-concrete blocks used in the quay walls off the coastline on a reclaimed land. For long-term durability, a concrete mix in which 50% and 70% of cement was replaced by ground blast furnace slag was used to cater for the durability performance requirements.

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Periodical:

Key Engineering Materials (Volume 711)

Pages:

444-452

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.711.444

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Online since:

September 2016

Authors:

K. Rahman Muhammad*, Al Omran Zaki, Ibrahim Mohammed, Al Nahdi Fahad, S. Barry Mohammed

Keywords:

Durability, Durability Indices, Ground Blast Furnace Slag, Marine Environment, Mass Concrete Blocks, Performance-Based Specifications, Quay Wall

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