Modification of cement matrices by the addition of micro particle pozzolanic materials such as silica fume and fly ash is known to improve the strength of concrete, but its contributions to fracture behavior remains unclear. In this study, the influence of replacing cement by silica fume and fly ash on the cement matrix-coarse aggregate interfacial bond, compressive stress-strain behavior and fracture behavior of concrete is investigated.; While the linear elastic fracture mechanics (LEFM) concept is not appropriate for concrete, a non-linear fracture model based on the load vs. load-line deflection and the load vs. crack-mouth-opening displacement (CMOD) responses of the three-point bend tests on notched beams is proposed and validated. Instead of using the LEFM based Two-Parameter Fracture Model that cannot adequately describes fracture processes in concrete, the proposed model is capable of generating the load vs. crack growth curve and the fracture resistance curve, and seems to be more appropriate for studying fracture behavior of concrete.; Incorporating silica fume in concrete mixture is found to have many beneficial effects on cement matrix-coarse aggregate interface, but less likely to improve the toughness of the cement matrix itself. The enhanced interfacial bond due to silica fume produces a more homogeneous concrete, which is responsible for the high strength, but more brittle concrete. It is shown that improving interfacial bond has positive effect on the pre-peak fracture behavior of concrete (e.g. the critical energy release rate, GC), but does not necessarily improve the overall fracture behavior (e.g. the fracture energy, GF, and the brittleness).; In this study, coal fly ashes were fractionated into various size ranges by the air classifier method. It is found that replacing cement by very fine fly ash (with average particle size less than 3 microns) can enhance both the toughness of cement matrix and the interfacial bond, which results in high strength and less brittle concrete. The coarser fly ashes, which are porous and less reactive, are shown to enhance the interfacial bond, but produce brittle cement matrix. By reducing the particle size of fly ash, incorporating fly ash in cement matrix can improve both the strength and brittleness of concrete.
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机译:通过添加微粉火山灰材料(例如硅粉和粉煤灰)来改性水泥基体可提高混凝土的强度,但其对断裂行为的贡献尚不清楚。本研究研究了用硅粉和粉煤灰替代水泥对水泥基-粗骨料界面结合,压缩应力-应变行为和混凝土断裂行为的影响。虽然线性弹性断裂力学(LEFM)概念不适用于混凝土,但是基于载荷与载荷线挠度以及载荷与裂纹口张开位移(CMOD)响应的非线性断裂模型提出并验证了带缺口梁的单点弯曲试验。代替使用无法充分描述混凝土断裂过程的基于LEFM的两参数断裂模型,所提出的模型能够生成载荷-裂纹增长曲线和断裂抗力曲线,并且似乎更适合于研究断裂行为。混凝土。已发现在混凝土混合物中掺入硅粉对水泥基-粗骨料界面有许多有益的影响,但改善水泥基本身的韧性的可能性较小。由于硅灰而导致的界面粘结增强,可产生更均匀的混凝土,这是高强度但更脆的混凝土的原因。结果表明,改善界面粘结对混凝土的峰前断裂行为(例如临界能量释放速率, G C )具有积极作用,但不一定能改善整体断裂行为(例如,断裂能, 和脆性)。在这项研究中,煤粉煤灰通过空气分级机方法被分为不同的大小范围。发现用非常细的粉煤灰(平均粒径小于3微米)代替水泥可以增强水泥基体的韧性和界面结合力,从而提高混凝土的强度和脆性。较粗的粉煤灰是多孔的,反应性较弱,显示出可以增强界面结合力,但会产生脆性的水泥基体。通过减少粉煤灰的粒径,将粉煤灰掺入水泥基体中既可以改善混凝土的强度,又可以改善其脆性。
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