水凝胶包埋细菌对混凝土愈合效率和抗压强度的影响

Ricardo Hungria , Marwa M. Hassan , Momen Mousa
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引用次数: 0

摘要

微生物诱导碳酸钙沉淀具有封闭微裂纹的能力,是一种很有前途的自修复混凝土技术。本研究的主要目的是评估添加水凝胶包裹细菌对混凝土抗压强度和自修复效率的影响。为了实现这一目标,制备了12套砂浆样品,包括三种不同的矿物前体(乙酸镁、乳酸钙和乳酸钠),两种浓度(67.76和75.00​mM/L)和在两种不同的生物条件下(有细菌和没有细菌)。此外,还制备了一组普通砂浆样品作为对照。对于每个样品组,制备三个砂浆立方体和三个梁,并进行压缩和弯曲强度测试。从压缩试验中发现,含有乳酸钙以及酵母提取物和细菌的样品显示出最好的结果。至于弯曲试验,一旦出现裂缝,梁将接受28​湿/干循环的d(16​浸水h和8​干燥h),其中监测底部裂纹宽度(在0、3、7、14、28​d的湿/干循环)。一旦确定了愈合效率最高的样本(含有乳酸钙和水凝胶包裹的细菌的样本),该研究就扩大到混凝土样本。为了评估细菌前体组合对混凝土力学性能的影响,对两组混凝土圆柱体(由三个对照样品和三个含有细菌和乳酸钙的样品组成)进行了压缩试验。抗压强度最大的样品是含有乳酸钙和细菌的样品,与对照样品相比,抗压强度提高了17%。此外,对混凝土试样进行了弯曲强度恢复分析,结果表明,28天后,对照组的弯曲强度恢复率优于含细菌变体(41.5%对26.1%)​d的湿/干循环。还对破裂的样品进行了愈合效率分析,结果表明对照组显示出最佳结果。这些结果是由于与含细菌的样品相比,对照样品显示出更窄的裂纹宽度。
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Effects of hydrogel-encapsulated bacteria on the healing efficiency and compressive strength of concrete

Microbial-induced calcium carbonate precipitation is a promising technology for self-healing concrete due to its capability to seal microcracks. The main goal of this study was to evaluate the effects of adding hydrogel-encapsulated bacteria on the compressive strength and the self-healing efficiency of concrete. To achieve this objective, 12 sets of mortar samples were prepared, including three different mineral precursors (magnesium acetate, calcium lactate, and sodium lactate), at two concentrations (67.76 and 75.00 ​mM/L), and under two different biological conditions (with and without bacteria). In addition, a set of plain mortar samples was prepared to serve as a control. For each sample set, three mortar cubes and three beams were prepared and subjected to compression and flexural strength tests. From the compression tests, it was found that the sample containing calcium lactate along with yeast extract and bacteria displayed the best results. As for the flexural tests, once cracked, the beams were subjected to 28 ​d of wet/dry cycles (16 ​h of water immersion and 8 ​h of drying), where the bottom crack width was monitored (at 0, 3, 7, 14, 28 ​d of wet/dry cycles). Once the sample with the highest healing efficiency was identified (the one containing calcium lactate and hydrogel-encapsulated bacteria), the study was scaled up to concrete specimens. Two sets of concrete cylinders (consisting of three control samples and three samples with bacteria along with calcium lactate) were tested under compression in order to evaluate the effect of the bacteria-precursor combination on the concrete mechanical properties. The samples that yielded the greatest compressive strength were the ones containing calcium lactate and bacteria, displaying an improvement of 17% as compared to the control specimen. Furthermore, a flexural strength recovery analysis was performed on the concrete specimens revealing that the control showed better flexural strength recovery than the bacteria-containing variant (41.5% vs. 26.1%) after 28 ​d of wet/dry cycles. A healing efficiency analysis was also performed on the cracked samples, revealing that the control displayed the best results. These results are due to the fact that the control specimen showed a narrower crack width in comparison to the bacteria-containing samples.

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