花岗岩循环爆破振动衰减规律与损伤演化机理试验

为了研究岩石在循环爆破作用下的动力学响应,本文对黑云母花岗岩试块进行了小型爆破试验,利用加速度传感器和声波测试仪,分别对循环爆破荷载下质点振动衰减规律与累积损伤演化机理进行了探析,并对不同装药量下花岗岩试块的裂纹扩展与断裂形态进行了比较。结果表明:萨道夫斯基公式对室内花岗岩试块的爆破振动衰减规律具有较好的适用性,拟合相关参数都处于0.90以上;花岗岩的爆破损伤随着爆破次数的增加而增加,且损伤值随着距爆心距离（爆心距）的增加而降低,近区损伤值迅速降低,降幅约为1.46/m,而中区和远区损伤值降低相对缓慢,约为0.57/m和0.13/m;花岗岩的破坏程度和装药量有较高的关联度,当药量较低时,岩块致裂所需要的爆破次数就越大;随着药量增加到一定程度,岩块在低爆破次数下就会发生破坏;此外,还发现随着装药量的增加,试块爆后破裂的块数呈现增加趋势,如较低药量时试样破裂成2块,较高药量下破裂成3~4块。     

A scaled charge weight superposition model for rapid vibration estimation

Rapid vibration estimation usually relies on charge weight scaling laws. These empirical curves that fit field data are sometimes involved in linear superposition models. A scaled charge weight superposition model combines the traditional charge weight scaling law within a linear superposition framework so that the influence of timing and blast design parameters may be assessed. The model involves an extra parameter of time overlap and poses a partial explanation for the over-estimation of blast vibration levels sometimes predicted by linear superposition models. It is suggested that the time overlap parameter be determined from measured vibration data. The new model recovers the Holmberg-Persson equation for near-field vibration from a single blast hole. Three examples compare the predictions of the new model with those from a linear superposition model. The results indicate a consistent, but not compelling demonstration of the predictive power of the scaled charge weight superposition model. Further verification studies are recommended using a wide range of blast types and scaled distances to points of interest. The new model lies between a traditional charge weight scaling law and a linear superposition model. It ignores waveform superposition explicitly but assumes non-linear interaction between adjacent charges in a blast within a user-defined time window. In that sense, the scaled charge weight superposition model offers an alternative method for rapid vibration estimation.     

Numerical prediction of blast‐induced stress wave from large‐scale underground explosion

This paper presents a numerical model for predicting the dynamic response of rock mass subjected to large‐scale underground explosion. The model is calibrated against data obtained from large‐scale field tests. The Hugoniot equation of state for rock mass is adopted to calculate the pressure as a function of mass density. A piecewise linear Drucker–Prager strength criterion including the strain rate effect is employed to model the rock mass behaviour subjected to blast loading. A double scalar damage model accounting for both the compression and tension damage is introduced to simulate the damage zone around the charge chamber caused by blast loading. The model is incorporated into Autodyn3D through its user subroutines. The numerical model is then used to predict the dynamic response of rock mass, in terms of the peak particle velocity (PPV) and peak particle acceleration (PPA) attenuation laws, the damage zone, the particle velocity time histories and their frequency contents for large‐scale underground explosion tests. The computed results are found in good agreement with the field measured data; hence, the proposed model is proven to be adequate for simulating the dynamic response of rock mass subjected to large‐scale underground explosion. Extended numerical analyses indicate that, apart from the charge loading density, the stress wave intensity is also affected, but to a lesser extent, by the charge weight and the charge chamber geometry for large‐scale underground explosions. Copyright © 2004 John Wiley & Sons, Ltd.     

Blast Induced Damage and Dynamic Behaviour of Hangingwalls in Bench Stoping

This paper presents the results of a comprehensive monitoring program designed to investigate the extent of blast induced damage experienced by rock masses extracted by bench stoping methods. An array of triaxial geophones and extensometers were used to monitor blast vibration attenuation and measure hangingwall deformations during stope extraction. In addition, pre and post surveys of the hangingwall rock mass were conducted using a TV borehole camera and cavity survey instrumentation. These surveys were later used to calibrate damage profiles into the stope hangingwalls.

Peak particle velocity, hangingwall deformation measurements and stope surveys were used to develop a site specific damage model that allowed engineers to asses drilling and blasting configurations to minimise the extent of pre-conditioning and damage. In addition the study included the analysis of the frequency response, displacements and accelerations experienced by the excavation as extraction and mine filling progressed. This work aimed at improving our understanding of the influence of blasting on the dynamic behaviour of stope hangingwalls.

The study demonstrated that estimates of the maximum extent of rock mass pre-conditioning and/or damage made through the application of the Holmberg-Persson approach compared well with measured results. In addition, the study found that dynamic loading imparted on an exposed hangingwall from subsequent stope blasting was also expected to contribute to rock mass weakening and that mine filling was crucial to arrest further deterioration. Hangingwall accelerations were used to demonstrate that larger openings may be more susceptible to dynamic loading.     

九寨沟MS3.2级余震薛家坝坡体地震动响应特征

为研究余震对山体的地震动响应规律,在九寨沟薛家坝斜坡山体安装地震台阵,对斜坡表面以及斜坡内部不同深度地震动进行监测研究。M_S3.2级余震触发了山脚及山顶4台强震记录仪,数据揭示:位于斜坡表面凸出位置的山体地形,地震的放大作用明显,同时水平向的加速度峰值大于垂直方向;对比山脚,斜坡表面2#-1监测点加速度峰值PGA最大,阿利亚斯强度值放大5倍以上,放大效应最大的方向在垂直向,加速度达到2.48倍,阿利亚斯强度达到5.24倍;随着向山体内部水平深度的加深高位放大效应逐渐衰减,PGA最大值由洞口2.48下降到2.03,阿利亚斯强度响应系数最大值由洞口5.84下降到3.92;自坡体表面水平向内,各监测点加速度峰值逐渐减小,在0~25 m内自坡表面向内加速度峰值下降最快,坡体内部下降幅度变小;傅氏谱表明,山脚的频率成分范围0~50 Hz,主频值大小为23 Hz左右,2#-1监测点频率范围较山脚未有明显变化,但主频值明显减小,在5 Hz上下;在斜坡上洞口傅氏谱频率成分复杂,随洞口向洞内水平加深,各监测点幅值及频率成分逐渐降低的趋势。研究表明,在地震作用下,随着加速度幅值的增大,地震动能量会呈几何倍数的增加,且山体表面是地震动能量最大的位置,若短时间振动能量超过岩体的强度,则会出现崩塌、滑坡,同时对工程建设的安全有极大的影响。     

钢板桩施工振动现场监测分析

本文采用自主设计的地面振动加速度监测系统对3个不同土性场地的钢板桩施工进行了现场监测,分析了钢板桩施工过程中的地面振动峰值加速度和振动频率特性,并探讨了振动衰减规律及对周边建筑物的影响。研究结果表明:土的强度对钢板桩施工振动的影响显著,钢板桩在低阻力土体中的贯入速率快,地面振动响应弱,而在高阻力的土体中贯入速率慢,地面振动相对大很多;钢板桩施工引起的地面径向和切向加速度在同一深度比较接近,且随着深度的增加有增大的趋势;振源距离和土性对钢板桩施工引起的地面振动主频率影响不大,地面振动主频率与桩锤施工频率之间呈较好的线性正相关关系;钢板桩施工振动在距振源4 m范围内衰减迅速,其施工对周围建筑物的最小安全距离要远小于挤土型桩基的施工。     

Experimental Study of Failure Zone in Soil and Rock Blast

In this paper, according to in situ experimental data of sonic, seismic, hole television, acceleration, velocity and visual investigaton after explosion, we consulted laboratory experimental results. Study in soil and rock blasr destroy effect and zone. By comparing with blast destroy zone of rock mass, vartical tunnel, parallal tunnel.     

土岩爆破中岩体和坑道爆破破坏分区的试验研究

本文根据声波法、地震法、钻孔电视、质点振动加速度、速度和爆后破坏现象宏观调查等现场实验数据和资料,并参照室内试验结果,研究了土岩爆破中岩体和坑道的爆破破坏效应及其分区、并将岩体、垂直坑道与平行坑道的爆破破坏分区作了对比。     

强夯地基处理振动效应的研究

强夯法是地基处理的重要方法之一,在进行强夯地基处理时要评价强夯振动效应,评价的基础正是强夯振动振幅和振动衰减规律。以昌平区沙岭新村工程场地为例,通过对回填场地进行强夯振动监测,分析了强夯振动最大振幅及其随距离的衰减规律,并用频率的四次多项式表示场地介质衰减指数。在场地介质作用谱和强夯激励谱的基础上,通过计算得到介质作用函数和强夯激励函数。通过不断积累强夯振动效应资料,建立起不同性质岩土体与场地介质作用函数之间的关系,进而明确工程岩土体的物理力学性质和动力学表现之间本构关系。     

The Influence of Burden on Blast Vibration

There is a common belief within the blasting community that increasing the burden will increase the blast vibration. In order to test this belief in a direct sense, it would be desirable to fire single blastholes with various burdens and monitor the vibrations at many locations. A review of past literature indicates that such direct tests are rare and only scant data is available. Nevertheless, a detailed analysis of this and associated past work (on small-scale blocks and choke blasts) shows no convincing evidence of an influence of burden on blast vibration. On the other hand, by considering the role of reflected waves in a simple analytical model, reasoning is given to show that the vibration might well be insensitive to burden. In view of the scant data available, it was decided to conduct trials of a direct nature, in which 13 single blastholes were fired to a free face. The burdens chosen were 2.6 m, 5.2 m and 10.4 m, and the vibration was measured at typically 10 locations over the range 5 m to 50 m from each hole. The results clearly show that the vibration is independent of such burdens. Furthermore, a side-by-side comparison of a choke blast with a free-face blast showed that the vibration from the holes in the choke blast was not higher than the vibration from the holes in the free-face blast. The present work also shows that vibration, although insensitive to burden, is not insensitive to the condition (i.e., the degree of damage) of the surrounding rock mass. In this regard, blastholes in undamaged ground produce a significantly higher vibration than blastholes in damaged ground. This might well be the reason why pre splits and drop-cuts are observed to produce relatively high vibrations, i.e., it is not because such blasts typically involve large burdens, but rather that they are usually initiated in relatively undamaged ground.     

强震作用下均质岩质边坡动力响应的振动台模型试验研究

近年来我国地震灾害频发,强震诱发边坡失稳作为地震中最为常见的次生灾害,致使我国的地震滑坡灾害数量位居全世界之首,针对强震作用下岩质边坡动力响应问题,采用铁粉、重晶石粉、石英砂、石膏、水作为相似材料,开展了均质岩质边坡振动台试验。详细分析了均质边坡模型在不同频率和幅值地震波输入下的地震动响应特征,发现当频率较低时,沿坡表水平距离方向上监测点的水平加速度放大系数是单调增大的,坡肩处水平加速度放大系数达到最大值,当频率进一步增大接近或者超过模型自振频率时,边坡模型不再呈现出典型的放大现象;相同幅值不同频率加载条件下,均质边坡模型的自振频率变化整体不太明显,而输入加速度幅值的变化对自振频率的影响更为显著,低频成分对模型损伤不明显,高频及自振频率附近频段对均质边坡的损伤更为强烈,导致模型的自振频率显著下降。该问题的研究对强震作用下岩质边坡地震动响应及变形破坏机理研究具有一定的指导意义。     

Predicting Overbreak from Blast Vibration Monitoring in a Lake Tap Tunnel - A Success Story

Tunnels are required to be constructed for meeting different human needs such as power generation, transportation, underground storage, sewage etc. The predominant method of excavation, world over, is drilling and blasting owing to its capability to meet changing geo-technical conditions. Irrespective of the purpose for which the tunnels are driven, all are plagued by overbreak problems. Tunnels driven for water conveyance in hydroelectric power projects, in particular, need to be excavated with minimum overbreak to minimise cost of permanent concrete lining. Thus, predicting overbreak assumes significant importance to design site-specific blasts for minimizing rock damage. This paper presents a brief review of existing PPV (Peak Particle Velocity) based blast-induced rock damage estimation criteria and attempts to outline the ground vibration threshold levels for overbreak/rock damage in a tunnel driven through compact basalt. Rock damage manifested as overbreak is measured and correlated with the possible threshold levels of PPV. Also, the PPV levels for crack initiation and widening are proposed. The case pertains to a lake tap horizontal tunnel of Koyna Hydro-electric Power Project, India which is a water feeder tunnel for a fully underground hydroelectric power project. The tunnel was driven under a shallow rock cover of average depth ranging from 20 to 25m beneath a fully charged water body. The parting rock is mainly compact basalt. Blasting was carried out in two rounds in a controlled manner, i.e., by limiting the maximum charge per delay based on ground vibration monitoring. Ground vibration generated with free face (in second round) has been modeled and a new ground vibration propagation equation is proposed for tunnel blasting including the effect of an extra free face. The threshold limits of PPV for different degrees of overbreak/rock damage are proposed from extrapolated vibration predictor equation. The actual overbreak in the tunnel, measured using a Planimeter, varied from 2.45 per cent to 17.75 per cent of the finished tunnel area. The predicted overbreak from extrapolated PPV measurements is compared against the measured overbreak to validate the proposed blast-induced rock damage (BIRD) assessment model. The PPV level for overbreak was found to exceed 2050 mm/s in compact basalt. A linear relationship between the overbreak and maximum charge per delay is also established to design a tunnel blast in similar formations.     

Reliability analysis of the induced damage for single-hole rock blasting

Rock explosion has always been a complex problem because neither rock characteristics nor explosion waves could be accurately estimated. As such, this imposes a high uncertainty on deterministic methodologies available for damage prediction. In this paper, by defining two damage zones around the blast hole, including crushed and cracked zones, a first-order reliability analysis (FORM) was adopted to address this issue. For this purpose, FORM was used in a double-loop algorithm, where the inner loop was responsible for converging the FORM, and the outer loop was assigned to feed the inner loop with new cases. Using such nested-loop algorithm, the probability of exceedance was calculated for any desired damage zone radius. The maximum effect of the involved parameters on the failure probability induced around the blast hole was additionally studied using a parametric reliability analysis. The results showed that the radii for crushed and cracked zones are limited to 0.5 and 4.2?m, respectively, so that the probability of going beyond these limits is less than 1%. Moreover, the analyses of decoupled explosions showed that increasing the gap between the explosion charge and wall of the borehole could severely reduce the failure probability; however, the maximum effect of decoupling ratio occurs in the small range of radii between 0.3?mm and 2.35?m.     

Numerical Analysis of Blast-Induced Stress Waves in a Rock Mass with Anisotropic Continuum Damage Models Part 1: Equivalent Material Property Approach

Summary This paper uses the concept of anisotropic damage mechanics to analyze dynamic responses of a granite site under blasting loads. An anisotropic continuum damage model is suggested to model rock mass behavior under blasting loads. The effects of existing cracks and joints in the rock mass are considered by using equivalent rock material properties obtained from both field and laboratory test data. The anisotropic damage accumulations are simulated by continuous degradation of equivalent material stiffness and strength during loading process and are calculated using the exponential function with respect to the principal tensile strain in three directions. The suggested models are programmed and linked to an available computer program Autodyn3D through its user's subroutine capability. Stress wave propagation and damage zone in the rock mass induced by underground explosions are simulated. Numerical results of damaged area, peak particle velocity and acceleration attenuation as well as acceleration time histories and Fourier spectra are compared with those from independent field tests.     

Productivity optimisation in weak sedimentary formations for improved coal production and roof stability—an approach

Far-field peak particle velocity (PPV) measurements were made in the roof while blasting in coal development drivages at Tandsi Mine, Western Coalfields Limited, India. The roof was fragile at this mine and was posing constant support problems for mining, resulting in low productivity. The PPV measurements have been used to decipher the damage zone in the roof. The extent of damage obtained has been compared to establish the threshold limits for the damage zone. Conversely, the maximum charge per delay that can be exploded is calculated and a suitable blast design has been recommended for maintaining the roof stability and pull. A roof vibration predictor equation has been developed that shows a consistent trend indicating that it may have future use in a similar geo-mining setup. The blast pattern recommended has reduced the damage extent, though marginally, but helped in improving pull. Critical PPV for incipient rock damage in underground coal mine development drivages under fragile roof were computed. The PPV level for incipient crack growth was found to vary from 500 to 800 mm/s while for overbreak it varied from 800 to 1200 mm/s. It was also observed that the location of cut holes, charge concentration and firing sequence were found to be responsible for the difference in their damage potential.     

采矿爆破振动波在岩溶区的传播影响因素分析

为研究不同情况下爆破振动强度衰变规律和振动对岩溶塌陷的影响,为当地矿山合理开采及减少地面塌陷灾害的发生提供可靠依据,对湖南水口山铅锌矿区进行现场爆破振动测试,并利用古丹铅锌矿实测数据作对比分析;试验矿区共布设4条测线,接收8组爆破振动数据。采用萨道夫斯基修正公式对采集的数据进行计算,以爆破产生的振动波频率及振动速度作为测试指标,对实测数据进行提取、处理,确定爆破振动波的频率及其在介质中的传播速度及地震波引发的质点振动峰值振速。试验结果表明:采矿活动是岩溶地面塌陷的主要影响因素;爆破振动波的频率衰减强度与其在岩土体中的传播距离和断层有关,振动波的传播速度受到岩土体性质、岩层结构特征、岩层走向等因素的影响。      

某港口工程地基处理中的强夯影响范围研究

强夯法是地基处理的一种常用方法,而确定强夯影响范围是强夯法应用的关键。结合某港口工程地基处理的实测资料,分析强夯振动在深度和广度上的影响范围,进而得出振动的位移、速度、加速度随距夯击点距离增大而逐渐衰减的曲线关系式。     

损伤条件下深部岩体巷道光面爆破参数研究

岩体条件复杂多变,为了提高光面爆破的适应性、改善光面爆破效果,对损伤条件下深部岩体巷道光面爆破参数进行研究。通过对深部岩体巷道光爆层原岩应力场、光面爆破机制和振动损伤特征进行分析,基于爆炸应力波和爆生气体综合作用理论,考虑高原岩应力和岩石损伤影响,提出了损伤条件下深部岩体巷道光面爆破参数确定的计算方法。研究表明, （1）高原岩应力相当于提高了岩石的抗拉强度,不利于炮孔初始裂纹的形成及贯通,宜减小周边眼间距;（2）岩石损伤后,其他条件不变,光面爆破的炮孔间距和抵抗线值可适当加大;（3）高原岩应力和损伤条件下,光面爆破的炮孔间距较小时,容易造成爆后围岩损伤,降低围岩的稳定性能,因此,提高爆破效果的同时应及时加强支护,以确保施工安全和围岩稳定;（4）本文提出的光面爆破参数计算公式,经现场爆破验证效果良好,适用于复杂多变的岩体环境。     

基于固有振动频率的危岩安全监测试验研究

危岩体在经历地震和强降雨之后其抗滑力下降,从而导致重力作用失稳,是一种常见的破坏形式。危岩块体的失稳破坏取决于岩体结构面的状况,随着结构面的张开及黏结程度下降,危岩块体会发生失稳而崩塌,基于常规位移监测方法难以达到危岩块体监测预警的目的。而固有振动频率可以有效反映岩体的物理力学参数的变化,进而可以对其安全性做出预判。基于模型试验,在保持下滑力不变的情况下,通过固有振动频率来对滑坡内部的黏结力和摩擦力等力学指标进行分析。通过实际静摩擦力是否达到最大静摩擦力的方法来科学判识岩体的稳定情况。试验结果得出：计算的摩擦力可以有效分析岩体的安全性,并证明固有振动频率在降低至6 Hz以下,岩体开始趋于破坏。同时,得出由于摩擦力破坏后期占据抗滑力的比重逐渐升高,最高达到抗滑力的80%,从而造成破坏末期摩擦力不降反升的情况。基于固有振动频率的监测,可对岩体的损伤做出定量判断,也可评估岩体静摩擦力指标,从而实现扰动后岩体的安全评价。这种基于振动模态的岩体安全监测与损伤评价新的技术思路,将在实际工程中发挥重大作用。     

主溜井冲击损伤机制分析及实测验证

为准确判断溜井受矿石冲击的损伤情况,基于影响溜井的损伤因素,构建了溜井受矿石冲击的损伤理论模型,并据此运用MATLAB计算获得矿石对溜井冲击的冲量分布。采用MADIS-FLAC3D数据耦合技术建立溜井冲击损伤数值模型,揭示了溜井冲击损伤的分布规律。综合运用空区激光探测系统（CMS）和大型矿床三维软件SURPAC,实现了对溜井垮塌三维信息的准确获取及可视化,并对所建立模型的计算分析结果进行了验证。结果表明：（1）根据溜井冲击损伤模型计算得到溜井受冲击的范围标高为-265.83～-292.28 m,冲量在此区间呈现先增大后减小的规律,在标高为-272.88 m处达到最大,为13.52 kN?S;（2）通过数值模型分析得到溜井受矿石冲击一侧在标高为-264.12～-294.88 m区间段发生了位移变化,并在相应区间段形成一定范围的塑性区,说明矿石冲击破坏了此处溜井围岩的稳定性;（3）数值分析得出的最大位移监测值出现的位置与探测模型垮塌区域的最大断面标高一致,实际探测获得的溜井垮塌最严重区域形态与数值模拟确定的塑性区相吻合。