Experimental and Analytical Investigation of Crack Spacing and Width for Overlaid RC Beams at Elevated Temperatures

Abstract: Cracking in overlay-strengthened RC structures significantly influences their structural performance; however, the effect of elevated temperatures on cracking behavior remains

“…The crack width w can be obtained from the crack spacing, as it is the tensile extension difference between the reinforcement and the concrete within the crack spacing [41]. Considering that the tensile strain of concrete is very small, the crack width can be derived from Equation (41). w = σ s E s S cr (41) where σ s = stress in the reinforcement at a cracked section, E s = modulus of elasticity of the reinforcement.…”

“…Considering that the tensile strain of concrete is very small, the crack width can be derived from Equation (41). w = σ s E s S cr (41) where σ s = stress in the reinforcement at a cracked section, E s = modulus of elasticity of the reinforcement.…”

Practical Prediction Models of Tensile Strength and Reinforcement-Concrete Bond Strength of Low-Calcium Fly Ash Geopolymer Concrete

“…The crack width w can be obtained from the crack spacing, as it is the tensile extension difference between the reinforcement and the concrete within the crack spacing [41]. Considering that the tensile strain of concrete is very small, the crack width can be derived from Equation (41). w = σ s E s S cr (41) where σ s = stress in the reinforcement at a cracked section, E s = modulus of elasticity of the reinforcement.…”

“…Considering that the tensile strain of concrete is very small, the crack width can be derived from Equation (41). w = σ s E s S cr (41) where σ s = stress in the reinforcement at a cracked section, E s = modulus of elasticity of the reinforcement.…”

Practical Prediction Models of Tensile Strength and Reinforcement-Concrete Bond Strength of Low-Calcium Fly Ash Geopolymer Concrete

“…Considering the crack spacing, by this time (the 1990s), many parameters were considered: the concrete cover c [8,9,[11][12][13], and/or the bar spacing [8,9,[11][12][13], and/or the steel stress σs [11], and/or the concrete properties (compressive strength f c , tensile strength f ct , elastic modulus E c ) [7,14,15], and/or the bond stress σ b [7,14,15], and/or the bond properties (if high bond bars or plain surface) [8], and/or the bar diameter φ [7][8][9]11,12,14], and/or the effective reinforcement ratio ρ eff (determined in an effective area of concrete in tension surrounding the reinforcement) [7][8][9]14,15], and/or coefficient which takes account of the distribution of strain (if bending or pure tension) [8]. In general, all models were derived from knowledge of RC elements subject to pure tension.…”

Revisiting Cracking in Reinforced Concrete Beams: An Updated Analysis

“…Concrete is the most widely used building material in the world. However, reinforced concrete (RC) structures might face durability problems (Zhang et al 2017a;Li et al 2019), most of which are caused by the corrosion of steel rebars induced by chloride ions (Mehta 1991). The influence of steel corrosion on an RC structure has the following aspects: First, rusting causes the steel volume to expand, causing the concrete to crack (Rodriguez et al 1994); Second, when a rebar is corroded, the cross-sectional area of the rebar is reduced (Ahmad 2003); Third, the bonding performance of rebar and concrete is decreased by the corrosion (Fang et al 2006).…”

C-FRCM Jacket Confinement for RC Columns under Impressed Current Cathodic Protection