共查询到19条相似文献,搜索用时 46 毫秒
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利用超声回弹检测技术,对3种不同钢纤维掺量的钢纤维增强橡胶高强混凝土试件进行超声波回弹测试和抗压强度试验,得出钢纤维橡胶高强混凝土的超声回弹综合法的专用测强曲线,为利用超声回弹检测技术对钢纤维增强橡胶高强混凝土的强度测试提供技术参考. 相似文献
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超短异型钢纤维高强混凝土性能研究 总被引:2,自引:1,他引:1
本文通过对比试验研究,探讨了超短导型钢纤维高强混凝土的力学性能和超声波速。证明超短异型钢纤维高强度混凝土可以解决钢纤维混凝土的搅拌均匀问题,并且适应现代化施工要求,从而可改善高强混凝土的抗拉抗剪强度,提高混凝土韧性;提出了采用超声测试技术可以推断钢纤维的掺入量和分布的观点。 相似文献
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本文通过对一批C40钢纤维混凝土试件进行超声波检测及抗压强度的试验研究,对试验结果进行了回归分析,建立了钢纤维混凝土检测的超声波声速与抗压强度之间的关系曲线,结果表明:利用该曲线测定超声声速可推定钢纤维混凝土的强度,超声波检测方法用于钢纤维混凝土无损检测是可行和适用的。 相似文献
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高强混凝土和钢纤维高强混凝土断裂性能试验研究 总被引:8,自引:0,他引:8
通过对C80高强混凝土(HBC)和钢纤维高强混凝土(SFHSC)试件断裂性能的测试,分析两类混凝土断裂性能特性,并通过多指标与普通混凝土比较,总结HSC和SFHSC的断裂性能。 相似文献
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超短钢纤维高强混凝土静力与动力抗压特性对比试验及分析 总被引:9,自引:1,他引:8
采用长度9mm、直径约0.45mm的平直型超短钢纤维,研制了钢纤维体积含量0%、3%和6%的钢纤维高强混凝土,对它们进行了准静态的压缩试验和冲击压缩试验,得到两种材料在不同应变速率下的全过程应力应变曲线,对比分析了静态和动态条件下钢纤维含量对超短钢纤维高强混凝土的影响。 相似文献
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通过钢纤维高强混凝土立方体抗压试验,探讨了粗集料最大粒径、水灰比和钢纤维体积率对钢纤维高强混凝土抗压强度的影响.结果表明:钢纤维掺量不同,粗集料最大粒径变化对抗压强度影响趋势不同;随着水灰比的减小,抗压强度逐渐增加;随着钢纤维体的增大,抗压强度逐渐增加.在分析试验结果的基础上,分别建立了水灰比、钢纤维体积率与抗压强度之间的关系式. 相似文献
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钢纤维高强混凝土的力学性能研究 总被引:10,自引:0,他引:10
通过掺入体积含量0 .6 % ~1.8 % 的短切钢纤维,与C60 ~C80 高强混凝土复合,制作钢纤维高强混凝土。研究了钢纤维高强混凝土的抗压、劈拉和抗弯强度以及抗弯韧性指数等参数的规律。探讨了钢纤维高强混凝土的强度复合机理和力学特性。 相似文献
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This paper illustrates parameter optimization of compressive strength of steel fiber reinforced high strength concrete (SFRHSC) by statistical design and analysis of experiments. Among several factors affecting the compressive strength, five parameters that maximize all of the responses have been chosen as the most important ones as age of testing, binder type, binder amount, curing type and steel fiber volume fraction. Taguchi analysis techniques have been used to evaluate L27 (313) Taguchi’s orthogonal array experimental design results. Signal to noise ratio transformation and ANOVA have been applied to the results of experiments in Taguchi analysis. The confirmation runs were conducted for the optimal parameter level combination, which is obtained from the results of the above methodologies. The maximum compressive strength has been observed as around 124 MPa. By using the optimal parameter level combination, the direct tensile strength and flexural strength tests have been conducted. The mean values at the age of 28 days are obtained as 7.5 MPa and 13 MPa respectively. In this study, it is clearly demonstrated that all main factors except steel fiber significantly contribute to the compressive strength of steel fiber reinforced high strength concrete, yet age and binder type are the most significant contributors. 相似文献
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利用Φ100 mm SHPB装置分别对60 MPa 强度等级的素混凝土及钢纤维掺量分别为0%,0.2%,0.4%和0.6%的混凝土进行冲击压缩试验,控制在 10/s~20/s,30/s~40/s和75/s~90/s的应变率范围内.以峰值应变和残余强度法,作为韧度评价指标.峰值应变基本随钢纤维含量增加而增加,但随应变率的上升,钢纤维含量对峰值应变的影响减弱.对于C60系列,准静态下,最大增强27% (C60V4),83/s时,最大增强7%(C60V2);应变率86/s左右时,峰值应变基本与钢纤维含量无关.同样,残余强度对应的应变值明显随纤维含量增加而增加,反映出钢纤维的增韧效果. 相似文献
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This paper presents experimental behaviour of eccentrically loaded plain and steel fiber high strength reinforced concrete and concrete-encased composite columns. In the experimental study, a total of 32 square section both reinforced concrete and composite column specimens were fabricated at 0, 0.5, 0.75 and 1.0% volume fractions of steel fiber contents to examine the effects of steel fibers on column behaviour. Besides this, the composite columns were constructed and tested using almost the same conditions with reinforced concrete columns to investigate the column experimental behaviour. The complete load−deflection behaviour and strength of column specimens were obtained and the results were discussed in the study. In addition, the column specimens were analysed based on a theoretical method considering the nonlinear behaviour of the materials. The presented experimental study indicates that the inclusion of steel fibers in the range 0.75 to 1.0% volume fraction improves confinement and ductility features of high strength reinforced concrete and composite columns significantly. 相似文献
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Taher Abu-Lebdeh Sameer Hamoush William Heard Brian Zornig 《Construction and Building Materials》2011,25(1):39-46
This paper presents the results of single-fiber pullout tests for deformed and smooth steel fibers embedded in the newly developed very-high strength concrete (VHSC) matrixes. The pullout test program involved four types of steel fibers, eight compressive strengths of VHSC matrixes, and two normal concrete strengths. Test results have shown that pullout behavior of different steel fiber reinforced VHSC composites is influenced by the matrix strength and fiber end condition (smooth, flat end, or hooked). Results reveal that both maximum pull-out load and total pullout energy increases as matrix strength increases for all deformed fibers that did not rupture. The test results also indicated that the increase in total pullout energy is more significant than that in peak load. 相似文献