A case study of blasting vibration attenuation based on wave component characteristics

A typical blasting vibration wave is a composite wave,and its attenuation law is affected by the type of dominant wave component.The purpose of the present study is to establish an attenuation equation of the peak particle velocity(PPV),taking into account the attenuation characteristics of P-,S-and R-waves in the blasting vibration wave.Field blasting tests were carried out as a case to specifically apply the proposed equation.In view of the fact that the discrete properties of rock mass will inevitably cause the uncertainty of blasting vibration,we also carried out a probability analysis of PPV uncertainty,and introduced the concept of reliability to evaluate blasting vibration.The results showed that the established attenuation equation had a higher prediction accuracy,and can be considered as a promising equation implemented on more complex sites.The adopted uncertainty analysis method can comprehensively take account of the attenuation law of blasting vibration measured on site and discrete properties of rock masses.The obtained distribution of the PPV uncertainty factor can quantitatively evaluate the reliability of blasting vibration,which is a powerful and necessary supplement to the PPV attenuation equation.

The Application of Dynamic Shock Mechanics Test in Engineering Blasting

With the continuous advancement of China’s infrastructure construction to the west,according to the geographic situation in the southwest region,such as mountainous areas and complex terrain,the road construction process is inevitably accompanied by earth and rock blasting.To improve the quality and safety of the project,this paper addresses the problems of land and rock blasting faced in the construction of mountain road projects,taking the research of rock dynamic mechanics test as the starting point,and using a combination of theoretical analysis and experimental research methods.The specific research content includes the following parts:dynamic impact compression test(SHPB),dynamic splitting tensile test,and stress-strain curve analysis of the test results,which provides the theoretical basis and numerical parameters for the numerical simulation of future engineering blasting.

Attenuation of rock blasting induced ground vibration in rock-soil interface

Blasting has been widely used in mining and construction industries for rock breaking.This paper presents the results of a series of field tests conducted to investigate the ground wave propagation through mixed geological media.The tests were conducted at a site in the northwestern part of Singapore composed of residual soil and granitic rock.The field test aims to provide measurement data to better understand the stress wave propagation in soil/rock and along their interface.Triaxial accelerometers were used for the free field vibration monitoring.The measured results are presented and discussed,and empirical formulae for predicting peak particle velocity (PPV) attenuation along the ground surface and in soil/rock were derived from the measured data.Also,the ground vibration attenuation across the soil-rock interface was carefully examined,and it was found that the PPV of ground vibration was decreased by 37.2% when it travels from rock to soil in the vertical direction.

Study on orientation fracture blasting with shaped charge in rock

On the basis of the theories of mechanics of explosive and rock fracture mechanics, the mechanism of crack initiation and its expansion of directional fracture controlled blasting with shaped charges in rock were studied, then the blasting parameters were designed and tested by a model test in laboratory and field experiment. The experimental and test results showed that the energy from blasting is directionally concentrated for the cumulative action. The directional expansion of cracks is satisfactory, the results of the model test and field test suggested that the orientation fracture blasting with shaped charge is a good means of excavating tunnels or cutting rock.

Shock-induced fracture of dolomite rock in small-scale blast tests

This paper attempts to study dolomite failure using small-scale blast tests.The experimental setup consisted of a cylindrical specimen with a central borehole fitted with a detonation cord inside a copper pipe.The specimen was confined using lead material.During the test,acceleration histories were recorded using sensors placed on the lead confinement.The results showed that heterogeneity and initial cracks significantly influenced the observed failure and cracking patterns.The tests were numerically represented using the previously validated Johnson-HolmquistⅡ(JH-2)constitutive model.The properties of the detonation cord were first determined and verified in a special test with a lead specimen to compare the deformation in the test with that of numerical simulation.Then,the small-scale blast test was simulated,and the failure of the dolomite was compared with the test observations.Comparisons of acceleration histories,scabbing failure,and number of radial cracks and crack density confirmed the overall repeatability of the actual testing data.It is likely that the proposed model can be further used for numerical studies of blasting of dolomite rock.

Damage evolution and fragmentation behavior of pyramid cut blasting under uniaxial compression

Pyramid cut blasting is an essential form of inclined hole cut blasting,but the in-situ stress effect of pyramid cut blasting is rarely studied.Based on the research background of pyramid cut blasting in a deep rock mass,the size,volume,and fragment size distribution of the blasting cavity before and after uniaxial compression were analysed by a model test.Otherwise,the damage and effective stress of the pyramid cut blasting were analysed with LS-DYNA numerical simulation.The results show that the damage and fragmentation of pyramid cut blasting are not only affected by blasting stress wave and blasting gas,but also affected by uniaxial compression.Under the influence of uniaxial compression,the blasting stress wave and blasting gas are more likely to damage the rock mass parallel to the uniaxial compression direction near the connecting line of blasting hole,and make the volume of cavity larger and the fragment rate lower.Additionally,uniaxial compression has a prominent influence during the middle and late stages of blasting.

Current State of Numerical Simulations and Testing for the Blast and Impact Protection of the Build Civil Engineering Infrastructure

The identification of the critical infrastructure has shown that the build civil engineering infrastructure is almost involved everywhere, even with the IT-infrastructure. Therefore, the passive safety of structures is demanded. Security associations have analysed that most assaults came along with explosion and impact scenarios, which amount in 80% of assaults. Consequently, these are the extraordinary loads the structures have to be planned and designed for. To carry out such an engineering job, the engineer has to be educated in multiple disciplines as physics, material science , continuum mechanics, numerical mechanics, testing, structural engineering and related specific fields as wave propagation etc. In this paper we will concentrate on the subjects of numerical simulation and testing.

爆炸荷载下聚脲涂覆含局部缺陷油气管道的失效判定研究

通过埋地静爆试验,对经聚脲弹性体材料加固的含局部缺陷埋地油气管道抗爆性能及损伤评价进行研究,同时结合所得试验数据进行数值模拟,建立了浅埋爆炸荷载下聚脲弹性体材料加固含局部缺陷埋地油气管道损伤失效评估准则。结果表明:在折合距离为0.23 m/kg 1/3试验条件的浅埋爆炸荷载作用下,含局部缺陷普通管道与含局部缺陷聚脲管道迎爆面均发生了明显凹陷变形,含缺陷聚脲管道凹陷变形量较前者降低28.87%,且管道迎爆面及端部连接处易于遭受损伤;含局部缺陷普通管道迎爆面超压高于含局部缺陷聚脲管道且变形响应时间早于后者,表明聚脲材料可以有效降低爆炸冲击波压力峰值和推迟爆炸冲击波的作用时间。在进行爆炸荷载作用下管道的损伤失效判定时引入衡量管道横截面变形的截面临界椭圆度指标,最终建立了基于管道截面临界椭圆度的聚脲涂覆含局部缺陷埋地油气管道的超压-冲量损伤准则及判定公式。

炮孔壁初始冲击压力直接测量试验研究

基于电测法构建出一套测试系统对孔壁压力进行直接测量,以获得现场岩石炮孔中的孔壁压力实测数据,根据灵敏度、抗冲击和抗干扰能力等参数,选择PVDF压电传感器作为压力测试系统的敏感元件;根据爆炸荷载的加载特性,选择并联25Ω碳膜电阻的电流模式作为系统的测试电路;最后根据带宽、采样率等参数选择示波器进行数据采集。将测试系统应用于高速公路边坡爆破开挖中,试验得到炮孔壁轴向距炸药0、0.1、0.2、0.3 m 4个位置的压力时程曲线,结果表明:在90/32的装药条件下,轴向距炸药0~0.3 m范围内,孔壁峰值压力范围为1 446~156 MPa;各测点的压力上升时间为6.1~1.5μs,距离炸药越近、压力上升时间越长;对试验值进行拟合,发现在轴向距炸药0~0.3 m范围内孔壁压力峰值呈幂函数递减。试验验证了孔壁压力直接测试系统的可靠性。

爆破振动作用下桥梁桩孔稳定性振动台试验研究

为了解爆破振动对邻近桥梁桩基成孔后桩孔稳定性的影响,以与山体爆破工程计划同时施工的某主跨280 m的斜拉桥为背景,设计、制作土箱和缩尺比1∶40桩孔模型开展振动台试验,研究桩孔孔壁的破坏特征、土体振动速度和动土压力的变化规律。结果表明:土体的振动速度峰值和动土压力峰值均随着爆破强度的增大而增大,在土体产生破坏后,土体的振动速度峰值和动土压力峰值均呈现出非线性增大趋势;爆破强度较小时土体的动土压力峰值曲线为U形,爆破强度较大时桩孔区域土体的动土压力峰值曲线为W形,桩孔中上部区域的动土压力峰值较大;山体爆破振动会使钢护筒底部与土体交界面以下桩孔的中上部区域出现破坏,应对山体爆破施工加强现场监测,桩孔附近的振动速度峰值不宜超过2 cm/s,以保障桩孔的稳定性。

构造煤层顶板爆破跨界面致裂增透机制研究及应用

深部煤炭开采地质条件恶化,原生煤在多期构造运动作用下形成松软低渗高瓦斯构造煤层,煤层钻孔施工困难,爆破增透产生的裂隙不发育且易于重新压实。针对目前构造煤层顶板爆破致裂增透关键技术没有得到根本突破问题,构建试验模型进行煤层顶板爆破相似模拟试验和数值分析,监测跨界面应力波传播和宏观三维裂隙演化形态,再现了爆破应力波传播和煤岩体内部损伤破坏过程。研究表明:(1)构造煤层爆破损伤范围主要集中在爆破孔和煤层上下煤岩交界面附近煤体;构造煤顶板爆破产生跨界面致裂卸压裂纹,爆破损伤沿爆破孔向四周岩体扩展,最后蔓延到煤层底板,爆破孔位置和上部煤岩交界面以及煤层内部的损伤较为严重。(2)爆破应力波从构造煤层顶板传播到煤岩交界面时发生波的透射和反射,透射的压缩应力波破坏煤体;反射的拉伸应力波反作用于煤岩交界面区域岩体。(3)爆破累积损伤产生的跨界面交叉裂纹卸压,使顶板岩层裂隙和构造煤层裂隙贯通,有利于构造煤层的瓦斯垂向运移流动和卸压瓦斯抽采。现场应用表明,煤层顶板爆破瓦斯抽采纯量及其浓度快速上升,瓦斯抽采纯量从爆破前的0.07 m^(3)/min提高到1.73 m^(3)/min,体积分数从10.46%上升到68.50%,并且长时间维持在较高水平。研究成果可为深部构造煤层瓦斯高效抽采提供理论基础和技术支持。

赵官矿切顶卸压沿空留巷爆破参数研究

以赵官矿2707W工作面为工程背景,对切顶卸压沿空留巷爆破参数进行研究。结合现场工程地质条件,选用双向聚能拉伸爆破技术对试验段顶板进行预裂。综合运用理论分析计算、现场爆破试验等手段,得到了合理的爆破参数:爆破钻孔深度8.0 m,切顶角度10°,炮孔间距600 mm,装药结构为5+4+3。通过现场钻孔窥视和矿压监测等手段验证了切顶爆破效果良好,在丰富切顶卸压沿空留巷爆破技术理论的同时,也为类似工况提供一定的工程借鉴意义。

露天矿山台阶爆破合理微差时间优选及应用

为了降低露天台阶爆破后的岩石块度,减少二次破碎成本,根据杨家岭矿山的实际地质情况建立有限元模型,研究了微差时间对岩石损伤程度的影响,分析了关键测点随延期时间变化的规律,最后开展现场试验并利用块度分析软件WipFrag4.0对爆后岩石进行块度分析。结果表明:随着微差时间的增加,岩石的损伤程度先增加后减小,在孔间、排间微差时间分别为40、70 ms时,岩石的损伤程度达到最大;通过在现场开展爆破试验发现,在孔间延期时间为35、40 ms,排间延期时间为65、70 ms时,块度主要集中在10 cm处,块度大于31.6 cm的占比分别为21.26%、23.19%,明显小于其他方案;分析后发现爆后块度分布规律与数值模拟得到的岩石损伤程度变化规律具有较好一致性,验证了数值模拟的准确性;通过数值模拟岩石损伤程度的量化与现场爆破试验相结合,为后续研究岩石损伤提供新思路。

爆炸驱动激波管冲击波压力参数研究

爆炸驱动激波管的作用是通过驱动段内的炸药爆炸产生冲击波,经扩张段的激波整形对目标物体进行平面波加载。为获得爆炸驱动激波管试验段内的冲击波超压环境,得到试验件的加载条件,通过数值模拟和量纲分析的方法,综合考虑装药质量、激波管结构尺寸、目标物体位置等参数的影响,建立冲击波压力峰值与上述参数之间的经验计算模型,并通过多种工况的考核试验对该模型的准确性进行了验证。结果表明:模型得到的计算值与试验值的平均相对偏差为10%,可满足工程应用的要求,且爆炸驱动激波管试验段内冲击波超压峰值主要与装药质量、爆心距、激波管直径及驱动段长度有关,其余参数的影响基本可以忽略。

封闭空间内爆载荷下结构响应试验及仿真研究

TNT在封闭空间内爆炸会发生燃烧反应并释放大量的能量,这些附加能量会对内爆载荷起到增强作用,为分析封闭空间内爆炸载荷作用下的结构动态响应。开展封闭空间爆炸试验,通过试验数据对称性验证,说明试验中压力测试结果准确可靠;然后开展数值计算研究,并探讨板厚、屈服应力和边界约束3个因素对靶板结构动态响应的影响。数值计算与试验结果的准静态压力吻合较好,靶板中心点初始峰值位移和最终位移的误差均小于5%,验证数值计算方法的可靠性;靶板中心点初始峰值位移和最终位移增大比例与板厚减小比例相当;靶板中心点初始峰值位移减小比例约为屈服应力增大比例的0.2倍,而最终位移的减小比例约为屈服应力增大比例的0.4倍。所采用的数值计算方法能够很好地模拟结构在封闭空间爆炸载荷作用下的响应,可为舰船抗爆结构设计提供一定参考。

大红山铜矿点柱预裂爆破损伤控制

地下矿山在采用房柱法或者房柱法嗣后充填采矿法开采的过程中,为保证采场的稳定性,往往会预留大部分的矿柱来支撑着上部岩体。目前采用的一些采矿方法在一定程度上会对矿柱的稳定性造成损伤,因此研究和预防矿柱损伤变得至关重要。通过对比大红山铜矿西矿段180中段360-B144采场常规点柱法回采与点柱边界预裂爆破法两个方案,对矿柱造成的损伤来研究矿柱的稳定性。结果表明,常规点柱法回采爆破对矿柱的损伤深度在1.47 m左右,而点柱边界预裂爆破对矿柱的损伤深度在1.21 m左右,点柱边界预裂爆破与常规点柱法回采爆破相比,对周边矿柱的损伤影响较小。点柱边界预裂爆破区矿柱岩体声速变化幅度为9.02%,小于常规点柱法回采爆破区矿柱岩体声速变化幅度14.65%。

基于CWM和CM的长滩露天矿深孔台阶爆破岩体可爆性评价

在深孔台阶爆破中,对不同地质条件下的岩体按其可爆性进行分级,是进行爆破参数优选优化,确定合理爆破参数的前提,对提高矿区生产爆破效率,改善爆破效果、降低爆破成本具有重要意义。结合长滩露天煤矿爆破开挖实际,通过现场单孔爆破漏斗试验、岩体声波测试、室内岩石力学试验,获取了岩体体可爆性分级相关指标。基于组合赋权(CWM)和云模型(CM)的可爆性分级方法,对长滩露天煤矿剥离岩体的可爆性进行了分级评价。结果表明长滩露天矿正在剥离爆破的4个平台岩体可爆性为:1130平盘主要分布灰绿色粗砂岩,可爆性为Ⅲ级(中等);1115平盘主要岩性为黄绿色中砂岩,可爆性为Ⅱ级(较难爆);1100平盘是紫红色砂质泥岩,可爆性为Ⅰ级(难爆);1145平盘主要以紫红色泥岩为主,可爆性为Ⅲ级(中等)。

干砂地基初始应力对爆炸波传播影响的模型试验

为了研究砂土地基初始应力对爆炸波压力峰值、上升时间、传播速度和初始应力动态卸载等传播规律的影响,开展多组干砂地基常重力和超重力爆炸模型试验.试验结果表明,初始自重应力会抑制爆炸波近区压力峰值的增长,而对远区的影响较小.初始应力的增加使得爆炸波上升时间更长,更易由冲击波衰减为弹塑性波,并使得爆炸波波速增大.超重力试验通过还原砂土地基的原型自重应力,能够模拟爆炸荷载诱发砂土地基初始应力动态卸载的过程,形成爆炸压力和土体初始应力动态卸载拉应力的耦合波,动态卸载拉应力持续时间更长.与爆炸波压应力的比冲量相比,初始应力动态卸载拉应力的比冲量随着传播距离的增加逐渐成为爆炸能量的主要部分,其产生的破坏作用不可忽视.

复杂爆炸载荷致肺损伤试验研究

为研究真实工况下人员在爆炸冲击波作用下的动态响应特性,开展某型云爆弹静爆作用下工事内仿人形装置(Anthropomorphic Test Device,ATD)和绵羊的毁伤试验研究。采用爆炸测试装置和简易假人作为研究对象,通过6发爆炸试验分析爆炸冲击波在ATD表面传播规律,开展2种人员损伤预测模型的对比分析。研究结果表明:在本试验工况下,冲击波和崩落的混凝土碎块是主要的毁伤元;爆炸冲击波在ATD表面首先发生反射,随后绕射至其他部位,压力曲线表现出非典型冲击波特征,反射叠加效应明显;在典型冲击波特征正压作用时间区间内,由于Axelsson损伤模型线性阻尼项的影响,求解的胸壁运动速度呈现出先增大至峰值后降低的现象;Axelsson损伤模型与UFC 3-340-02规范相比,在人员损伤预测方面相对保守。所得研究结果可为工程应用及毁伤评估提供参考。

接触爆炸下混凝土墩破坏效应试验与数值模拟

为研究混凝土墩在炸药接触爆炸作用下的破坏效应,分别采用K&C模型、HJC模型、RHT模型和Kong-Fang模型对混凝土墩体的破坏效果进行数值模拟,讨论破坏形态、裂缝数量、块体数量、芯部残高和侧面残高的变化并与试验对比。研究结果表明,4种模型都能有效地预测混凝土墩体的破坏形态:在顶部集团装药爆炸作用下,混凝土墩体上半部分和下半部分表现为不同的破坏形式,上半部分为破碎性破坏,形成大量1~10 cm为主的碎块;下半部分为破裂性破坏,开裂为有限数量的块体;其中Kong-Fang模型能够更加可靠地预测破裂区块体的数量和残高。残留块体破坏特征参数随装药量的变化的研究结果表明,随着装药量从1.0 kg增加到4.5 kg,块体的数量增加到25,块体底面尺寸由40 cm减小为15 cm,约为混凝土底边尺寸的1/5~1/25;装药量从1.0 kg增加到3.5 kg时芯部残高及侧面残高减小较快,在装药量增加到4.0 kg后,分别稳定在40 cm及28 cm左右处,不再明显变化。基于以上研究结果,拟合了块体数量、芯部残高及侧面残高随装药量的变化公式,为有效实施混凝土墩体爆破作业提供了参考。