Effects of Silica Fume Addition on the Spalling Phenomena of Reactive Powder Concrete

Kai Pei Tian; Yang Ju; Hong Bin Liu; Jin Hui Liu; Li Wang; Peng Liu; Xi Zhao

doi:10.4028/www.scientific.net/AMM.174-177.1090

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Development of Mix Proportion for High-Performance Concrete Using Locally Available Ingredients Based on Compressive Strength and Durability
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Adsorption Characteristics of Surfactant on Slag in Alkali Activated Slag Cement System
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Properties of Artificial Lightweight Aggregates (ALAs) Made of Dredged Soil Mixed with Waste Catalyst Slag
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Research and Applying Evolution of Admixture for High Performance Concrete
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Effects of Silica Fume Addition on the Spalling Phenomena of Reactive Powder Concrete
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Water-Soluble Cr (VI) of Solidification-Cured Process and Compressive Strength of Ferrochrome Slag Complex Cement
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Predication of GRT Fiber-Rubberized Haydite Concrete Bend Strength Based on Multiple Regression Analysis and BP Neural Network
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The Effect of UV Light and Xenon Lamp on Anti-Aging Properties of Recycled Milk-Cartons/PE Composite Siding
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The Effects of Water-Reducer on Early-Age Plastic Shrinkage of Concrete
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 174-177Effects of Silica Fume Addition on the Spalling...

Effects of Silica Fume Addition on the Spalling Phenomena of Reactive Powder Concrete

Abstract:

The explosive spalling of high-strength concrete due to fire is a problem that has garnered increasingly widespread attention, particularly the explosive spalling of reactive powder concrete (RPC). For years, based on the vapor pressure mechanism, the addition of fibers has been demonstrated to be somewhat effective in protecting against spalling. However, relevant experiments indicate that fibers are not effective for dense concrete, which is a challenge for the simple vapor pressure mechanism in providing spalling resistance for RPC. The authors found that silica fume plays an important role in the explosive spalling of RPC. Thus, four classes of RPCs with different ratios of silica fume were prepared, and the spalling phenomena and the inner temperature distribution during heating were investigated. The results show that silica fume content has a prominent effect on the spalling process of RPC.