The effect of post-fire-curing on strength–velocity relationship for nondestructive assessment of fire-damaged concrete strength

“…These techniques can produce a detailed set of data related to the mechanical characteristics of materials, see for example [21][22][23][24] and [40][41]. In particular, the velocity of ultrasonic transit pulses in undamaged concrete can reach and exceed 5000 m/s, see [22].…”

“…With the aim of presenting a general procedure for RC assessments after fire, in this work several methods are presented and tested referring to an interesting real case-study: visual examination, destructive and non destructive tests like pull out, sonic and ultrasonic test, sclerometer and SonReb test (see for example [21][22][23][24]) can produce a detailed set of data related to the mechanical characteristics of materials. Other effective techniques capable of determining fire damage on concrete are: microscopic analysis (optical and electronic), see [25][26][27][28][29][30][31], Thermogravimetric analysis (TGA), combined with Differential Thermal Analysis (DTA), see [32][33], X-ray diffractometry (XRD), see [34][35] and colorimetry, see [31], [36][37][38].…”

Integrated Approach for Post-fire Reinforced Concrete Structures Assessment

“…These techniques can produce a detailed set of data related to the mechanical characteristics of materials, see for example [21][22][23][24] and [40][41]. In particular, the velocity of ultrasonic transit pulses in undamaged concrete can reach and exceed 5000 m/s, see [22].…”

“…With the aim of presenting a general procedure for RC assessments after fire, in this work several methods are presented and tested referring to an interesting real case-study: visual examination, destructive and non destructive tests like pull out, sonic and ultrasonic test, sclerometer and SonReb test (see for example [21][22][23][24]) can produce a detailed set of data related to the mechanical characteristics of materials. Other effective techniques capable of determining fire damage on concrete are: microscopic analysis (optical and electronic), see [25][26][27][28][29][30][31], Thermogravimetric analysis (TGA), combined with Differential Thermal Analysis (DTA), see [32][33], X-ray diffractometry (XRD), see [34][35] and colorimetry, see [31], [36][37][38].…”

Integrated Approach for Post-fire Reinforced Concrete Structures Assessment

“…In addition, Lin et al found that, after recuring in the air for 6 months, the residual compressive strength of air-cooled concrete exposed to 600°C was only 28% of the original strength [13]. However, the residual compressive strength of concrete with SCC increased from 51% to 64%.…”

“…It is now realized that the fire-damaged concrete could regain part of the properties with post-fire-curing due to the rehydration of the C-S-H gel [8][9][10][11][12][13][14][15]. The heating temperature and the recuring conditions were considered as the main influence factors on the recovery of concrete exposed to elevated temperature [8,9].…”

“…The heating temperature and the recuring conditions were considered as the main influence factors on the recovery of concrete exposed to elevated temperature [8,9]. Most researchers concluded that water played an important part in the rehydration of concrete exposed to elevated temperature [10,13,14,16].…”

The use of surface coating in enhancing the mechanical properties and durability of concrete exposed to elevated temperature

Physical-mechanical behavior of concretes exposed to high temperatures and different cooling systems