冯国瑞, 马敬凯, 李竹, 戚庭野, 崔家庆, 郭伟, 赵彦同, 侯斌. 破碎围岩注浆加固体承载特性与损伤破坏机制[J]. 煤炭学报, 2023, 48(S2): 411-423. DOI: 10.13225/j.cnki.jccs.2022.1265
引用本文: 冯国瑞, 马敬凯, 李竹, 戚庭野, 崔家庆, 郭伟, 赵彦同, 侯斌. 破碎围岩注浆加固体承载特性与损伤破坏机制[J]. 煤炭学报, 2023, 48(S2): 411-423. DOI: 10.13225/j.cnki.jccs.2022.1265
FENG Guorui, MA Jingkai, LI Zhu, QI Tingye, CUI Jiaqing, GUO Wei, ZHAO Yantong, HOU Bin. Bearing characteristics and damage mechanism of grouting reinforced body for broken surrounding rock[J]. Journal of China Coal Society, 2023, 48(S2): 411-423. DOI: 10.13225/j.cnki.jccs.2022.1265
Citation: FENG Guorui, MA Jingkai, LI Zhu, QI Tingye, CUI Jiaqing, GUO Wei, ZHAO Yantong, HOU Bin. Bearing characteristics and damage mechanism of grouting reinforced body for broken surrounding rock[J]. Journal of China Coal Society, 2023, 48(S2): 411-423. DOI: 10.13225/j.cnki.jccs.2022.1265

破碎围岩注浆加固体承载特性与损伤破坏机制

Bearing characteristics and damage mechanism of grouting reinforced body for broken surrounding rock

  • 摘要: 注浆加固是提升破碎围岩整体性及其承载性能的重要途径,破碎围岩注浆加固体强度、损伤变形及其破坏特征决定加固体抵御外载扰动并维持围岩稳定的能力。选用不同粒径的破碎岩体并注入不同质量浓度水泥净浆,自凝固形成破碎围岩注浆加固体。基于声发射监测和DIC变形测量技术,探究破碎围岩注浆加固体力学承载机制,掌握"声发射-应力-表面位移"耦合规律及其动态响应特征,阐明注浆对破碎围岩承载能力的强化效应及加固体二次承载损伤破坏失稳机制,据此建立破碎围岩注浆加固体承载损伤本构模型。结果表明:①注浆加固体峰值强度随粒径的增大而减小,随水灰比的提高而降低。以水灰比0.4为例,粒径从5~10 mm增加到20~30 mm,注浆加固体强度从23.99 MPa降低到19.30 MPa,降幅达19.55%;以破碎岩石粒径为5~10 mm为例,水灰比从0.4增加到0.6,加固体强度从23.99 MPa降低到14.83 MPa,降幅达38.18%。此外,注浆加固体峰后阶段并未发生典型岩石材料的脆性破坏,应力-应变峰后曲线多次"起伏式"下降,呈现出良好的延展性和韧性变形特征。②声发射振铃累计次数曲线表现出明显的"上升期-活跃期-平静期"3个阶段。注浆加固体中破碎体粒径越小,上升期跨度越大,平静期声发射事件相对越频繁;浆液水灰比越高的加固体,声发射振铃次数总体水平越低。③基于声发射b值和DIC的联合监测,发现了声发射b值和注浆加固体试件内部裂缝尺度的对应关系,即"小b值大裂缝"和"大b值小裂缝",且粒径大小与加固体试件裂缝尺度正相关,粒径越大,裂纹发育及扩展越明显,表面大应变集中带分布范围更广,裂纹开度更大,损伤破坏更严重。④根据测得的注浆加固体弹性模量、峰值应力和峰值应变,建立了破碎围岩注浆加固体损伤本构方程,据此可以预测不同粒径的破碎岩体和不同浆液质量浓度形成的注浆加固体力学强度,以期为注浆加固体强度设计及工程岩体稳定性评价提供参考。

     

    Abstract: Grouting reinforcement is an important way to improve the integrity of the broken surrounding rock and its bearing capacity, the strength, damage deformation and failure characteristics of grouting reinforced body for broken surrounding rock determine the ability of the reinforcement body to resist external load disturbance and maintain the stability of the surrounding rock. Broken rock mass with different particle sizes were selected and cement slurry with different concentrations was injected, and the grouting reinforced body for broken surrounding rock was formed by self-solidification. Based on acoustic emission (AE) monitoring and the DIC deformation measurement technology, in this study, the mechanical bearing mechanism of the grouting reinforced body for broken surrounding rock was explored, and the "AE-stress-surface displacement" coupling law and its dynamic response characteristics during the process were obtained. Also, the strengthening effect of grouting on the bearing capacity of broken surrounding rock, and the mechanism of secondary load-bearing damage and instability of reinforced body were clarified. Based on this, the damage constitutive model of grouting reinforced body bearing capacity of broken surrounding rock was established. The results show that:① the peak strength of the grouting reinforced body decreases with the increase of particle sizes, and decreases with the increase of water-cement ratio. Taking the water-cement ratio 0.4 as an example, the particle size increases from 5-10 mm tO20-30 mm, and the grouting reinforced body strength decreases by 19.55% from 23.99 MPa to 19.30 MPa. Taking the particle size of 5-10 mm as an example, the water-cement ratio increases from 0.4 to 0.6, and the grouting reinforced body strength decreases from 23.99 MPa to 14.83 MPa, a decrease of 38.18%. In addition, the brittle failure of typical rock materials does not occur in the post-peak stage of grouting reinforced body, and the stress-strain post-peak curves repeatedly decrease "undulating", showing good ductility and toughness deformation characteristics. ② The curves of accumulative times of AE ringing show obvious three stages of "rising period-active period-quiet period". The smaller the particle sizes of the broken rock in the grouting reinforced body, the larger the span of the rising period, and the more frequent the AE events in the quiet period. The higher the water-cement ratio of the slurry, the lower the overall level of AE ringing times. ③ Based on the joint monitoring of the AE b-value and DIC, the corresponding relationship between the AE b-value and the internal crack sizes of the grouting rein-forced body specimens is found, namely "small b-value large crack" and "large b-value small crack". And the particle sizes are positively correlated with the crack sizes of the reinforced specimens. The larger the particle sizes, the more obvious the cracks' development and expansion, the wider the distribution range of the large strain concentration zone on the surface, the larger the crack opening, and the more serious the damage. ④ The elastic modulus, peak stress, and peak strain of the grouting reinforced body are measured, the damage constitutive models of the grouting reinforced body for broken surrounding rock is established. According to this, the mechanical strength of the grouting reinforced body formed by the broken rock mass with different particle sizes and different slurry concentrations can be predicted, which can provide some references for grouting reinforced body strength design and the evaluation of engineering rock mass stability.

     

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