通过开展在不同龄期、不同环境湿度下玻璃纤维增强水泥(GRC)试件的抗折强度、抗压强度试验和基体pH值测定,研究了环境湿度对掺加粉煤灰和硅灰等活性矿物掺合料的GRC试件力学性能的影响。结果表明:环境湿度对GRC试件的抗折强度有重要影响,相对湿度越大,随着龄期增加,GRC试件抗折强度降低越严重;在温度60℃、相对湿度95%条件下,经过56d龄期后,掺有40%粉煤灰和10%硅灰的GRC试件抗折强度比未掺加粉煤灰和硅灰的GRC试件的抗折强度提高48.5%、抗压强度提高23.6%,GRC基体pH值降低6%。在相同的湿度条件下,掺有粉煤灰和硅灰试件的pH值在各个龄期都低于普通硅酸盐水泥试件,说明粉煤灰和硅灰的掺入能降低水泥水化液相的碱度,进而延缓了纤维受侵蚀的速度,显著改善了GRC试件的力学及耐久性能。通过对试验结果进行分析,利用MATLAB软件建立了GRC试件抗折强度和抗压强度与水泥砂浆基体pH值及时间的关系式。
Through the determination of flexural strength,compressive strength test and matrix pH value test of glass fiber reinforced cement (GRC)specimens under different ages and ambient humidities,the effects of ambient humidity on the mechanical properties of GRC specimens blended with active mineral admixtures of fly ash and silica fume were researched.The results show that the ambient humidity has a significant effect on the flexural strength of GRC specimens.With the increase of the age,the higher relative humidity is,the more flexural strength of GRC specimens reduces.After 56 d age on the condition of temperature of 60 ℃ and relative humidity of 95%,the flex-ural strength and compressive strength of GRC specimens blended with 40% fly ash and 10% silica fume both in-crease by 48.5% and 23.6% respectively,meanwhile the pH value of GRC matrix decreases by 6% in comparison to those without fly ash and silica fume.On the same condition of ambient humidity,the pH values of specimens blended with fly ash and silica fume are lower than those of ordinary portland cement specimens in every age,which shows that the addition of fly ash and silica fume can reduce the alkalinity of cement hydration liquid phase and slow down the corrosion rate of fibers.So it can dramatically improve the mechanical property and durability of GRC specimens.Based on the analysis of the test results and MATLAB software,the mathematical relationship between the mechanical properties of GRC specimens including the flexural strength and compressive strength and the pH value of cement mortar matrix,the age can be established.
参考文献
| [1] | 韩静云;蒋家奋.欧洲玻璃纤维增强水泥(GRC)的回顾与展望[J].混凝土与水泥制品,2003(6):33-38. |
| [2] | Wen Liang;Jijian Cheng;Yingjie Hu;Hui Luo.Improved properties of GRC composites using commercial E-glass fibers with new coatings[J].Materials Research Bulletin: An International Journal Reporting Research on Crystal Growth and Materials Preparation and Characterization,20024(4):641-646. |
| [3] | 汪宏涛;曹巨辉;薛明;杨铁军.玻璃纤维对GRC复合材料耐久性的影响[J].后勤工程学院学报,2009(2):1-4. |
| [4] | 许红升;杨小平;苏素芹;张锦峰;王玉洪;李国忠.碱性环境条件下玻璃纤维的侵蚀性研究[J].腐蚀与防护,2006(3):130-132,135. |
| [5] | 葛敦世.玻璃纤维碱侵蚀机理和耐碱性的探讨[J].玻璃纤维,2007(01):1-9,14. |
| [6] | J. Paya;M. Bonilla;M.V. Borrachero.Reusing fly ash in glass fibre reinforced cement: A new generation of high-quality GRC composites[J].Waste Management,200710(10):1416-1421. |
| [7] | P. Purnell;J. Beddows.Durability and simulated ageing of new matrix glass fibre reinforced concrete[J].Cement & concrete composites,20059/10(9/10):875-884. |
| [8] | Alejandro Enfedaque;Laura Sanchez Paradela;Vicente Sanchez-Galvez.An alternative methodology to predict aging effects on the mechanical properties of glass fiber reinforced cements (GRC)[J].Construction and Building Materials,20121(1):425-431. |
| [9] | Batalin, B. S.;Saraikina, K. A..Interaction of Glass Fiber and Hardened Cement Paste[J].Glass and ceramics,20147/8(7/8):294-297. |
| [10] | 徐洪国;水中和;章瑞;陈伟;曾俊杰.偏高岭土对水泥石热膨胀性能的影响[J].硅酸盐通报,2011(2):278-282. |
| [11] | 吴浩;姚燕;王玲.减缩剂对水泥石体积稳定性的影响及其机理[J].硅酸盐学报,2010(3):478-485. |
| [12] | Enfedaque, A.;Galvez, J. C.;Suarez, F..Analysis of fracture tests of glass fibre reinforced cement (GRC) using digital image correlation[J].Construction and Building Materials,2015Jan.30(Jan.30):472-487. |
| [13] | H. Cuypers;J. Wastiels;P. Van Itterbeeck.Durability of glass fibre reinforced composites experimental methods and results[J].Composites, Part A. Applied science and manufacturing,20062(2):207-215. |
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