Anisotropic creep behavior of soft-hard interbedded rock masses based on 3D printing and digital imaging correlation technology

Three-dimensional(3D)printing technology is increasingly used in experimental research of geotechnical engineering.Compared to other materials,3D layer-by-layer printing specimens are extremely similar to the inherent properties of natural layered rock masses.In this paper,soft-hard interbedded rock masses with different dip angles were prepared based on 3D printing(3DP)sand core technology.Uniaxial compression creep tests were conducted to investigate its anisotropic creep behavior based on digital imaging correlation(DIC)technology.The results show that the anisotropic creep behavior of the 3DP soft-hard interbedded rock mass is mainly affected by the dip angles of the weak interlayer when the stress is at low levels.As the stress level increases,the effect of creep stress on its creep anisotropy increases significantly,and the dip angle is no longer the main factor.The minimum value of the long-term strength and creep failure strength always appears in the weak interlayer within 30°–60°,which explains why the failure of the layered rock mass is controlled by the weak interlayer and generally emerges at 45°.The tests results are verified by comparing with theoretical and other published studies.The feasibility of the 3DP soft-hard interbedded rock mass provides broad prospects and application values for 3DP technology in future experimental research.

Precise 3D shape measurement of three-dimensional digital image correlation for complex surfaces

Three dimensional-digital image correlation （3D-DIC） is a widely used optical metrology in the experimental mechanics community because of its reliability, practicality, and flexibility. Although the precision of digital image correlation （DIC） has been thoroughly studied theoretically and numerically, verification experiments have seldom been performed, especially fbr complex surfaces with a small field of view （FOV）. In this work, the shape of a 1-yuan coin was measured using 3D-DIC; the shape was complex due to the presence of many fine details, and the FOV was relatively small because the coin diameter was only 25 mm. During the experiment, a novel strategy for speckle production was developed： white paint was simply sprayed onto the surface. Black paint was not used; instead, taking advantage of the reflective nature of the coin surface, polarized light and a Polaroid filter were introduced, and the polarization direction was carefully adjusted, ensuring that the spray pattern was extremely thin and that high-quality speckle images with significant contrast were captured. The three-dimensional coin shape was also successfully determined for comparison using a stylus profiler. The results demonstrate that 3D-DIC provides high precision in shape measurement even for complex surfaces with small FOV. The precision of 3D-DIC can reach 1/7000 of the field of view, corresponding to about 6 ~tm in this experiment.

Fine Characterization and Analysis of Drying Strain of the ELM Board via DIC Technology

In this paper,the occurrence and development mechanism of strain on the cross-section during the wood drying is explored.Therefore,strain regularity on the cross-section of 50 mm thickness elm(Ulmus rubra)board at the temperature of 40℃and 80℃is detected via digital image correlation technology.Hence,the difference between tangential and radial strain at surface and core layers was denoted.The results showed that strain distribution in the width direction of the board is uneven.Moreover,a large drying shrinkage strain occurs at the near-core layer,while the maximum strain difference reaches 4.08%.Hence,the surface of the board is cracked along the thickness direction.The radial strain of the board is higher than the tangential strain in the early stage of drying,while these strains are reversed in the later stage of drying.The temperature is related to the difference between the tangential and radial strains of the elm board.These differences at the core layer are larger than those of the surface layer.The conducted research results provide a theoretical basis for process optimization.

Three-Dimensional Volumetric Analysis of Venous Malformations for Assessing the Effectiveness of Percutaneous Sclerotherapy

BACKGROUND Percutaneous sclerotherapy can be used to successfully treat venous malformations(VMs)of the head,neck,and limbs.However,the standard curative effect of sclerotherapy has rarely been analyzed,and there is currently no accurate statistical method to measure the volume of VMs after sclerotherapy.Here,we propose a novel threedimensional(3D)reconstruction method to evaluate this effect.OBJECTIVE To test the feasibility of 3D software(MIMICS 19.0)to evaluate the treatment effect of sclerotherapy.METHODS This retrospective study included patients with VMs on the head,neck,and limbs who were treated with ethanol sclerotherapy or foam sclerotherapy every 8 weeks.MIMICS 19.0 was used to calculate the performance of the lesion after treatment and measure the VM volumes before and after the treatment.The effect of the clinical treatment dose on the lesion was evaluated,and the treatment effect of each patient was recorded.The relationship between the number of treatments and the reduced volume of VMs was analyzed.RESULTS Based on the MIMICS-calculated regions of interest(ROI),we found that 1 mL of ethanol reduced the lesion by 473 mm3 and that one dosage of foam(1 mL of polidocanol and 4 mL air content)reduced the lesion by 2138 mm3,demonstrating that the foam sclerosing agent exhibited greater efficacy in this study.CONCLUSIONS The MIMICS 3D volume reconstruction method can effectively and safely evaluate the efficacy of sclerotherapy and provide a preoperative evaluation.This method is simple,accurate,and feasible.

定向断裂控制爆破下层理页岩的致裂机理

为探究定向断裂控制爆破下层理页岩的爆破致裂机理,采用切缝药包,对四种切缝角度下的页岩立方体试件进行爆破试验,采用数字图像相关技术(DIC)对页岩试件表面应变场的演化过程进行监测,分析了微裂纹孕育至宏观裂纹贯通的内在机理,并基于盒维数理论计算了不同切缝角度下页岩试件表面裂纹的分形维数,采用Matlab软件对爆后块度的筛分方法进行了编程分析,开发了全自动的粒径分析程序,实现了粒径圈定的可视化。试验结果表明:试件在不同比例爆距内的裂纹总密度与比例爆距之间存在负相关的幂函数关系,切缝方向与层理弱面的夹角对微观损伤区域出现的位置影响显著,当层理弱面与切缝方向平行时,损伤区域多集中于层理弱面处,对宏观裂纹的扩展路径影响显著,易于形成单一裂纹;层理弱面处的能量泄漏是造成页岩爆破破碎效果较差的重要因素,当切缝方向与层理弱面一致时,试件爆后的大块占比较高,爆后块度的分形维数平均值在各组间最低,仅为0.7843,而当切缝方向与层理面垂直时,试件的爆后块度分布较为均匀,爆后块度的分形维数平均值达到了2.5233,爆破破碎效果相对较好。

基于声发射和DIC的金属材料氢脆性能测试实验

该实验针对天然气掺氢管道混输过程中产生的临氢金属氢脆问题,以X80管线钢为对象,采用声发射与数字图像相关(DIC)技术相结合的方法实现氢脆性能的动态测试。实验设计为对材料进行充氢后拉伸,采用电化学充氢法充氢,并设置4种不同充氢时间。拉伸过程中通过DIC技术测量并计算静态氢脆性能参数和氢脆敏感系数,同时利用等效应变云图和声发射计数峰值时域分布的变化规律作为氢脆性能的动态参量,进而建立一套完整的金属氢脆性能动态测试系统。该实验适合作为学生研究型教学实验,有助于培养学生的科研能力和创新意识。

温拌再生沥青砂浆二次老化前后抗反射开裂性能评价

为研究温拌再生沥青路面的抗反射开裂性能,结合Overlay Tester(OT)试验与数字图像相关(Digital Image Correlation,DIC)技术,研究了长期老化后废旧沥青混合料(Reclaimed Asphalt Pavement,RAP)掺量对温拌再生沥青砂浆抗反射开裂性能的影响。研究结果表明:经过二次老化后,RAP掺量对温拌再生沥青砂浆的抗反射开裂性能影响显著,二者成负相关关系;在相同的老化条件下,不同RAP掺量的再生沥青砂浆裂缝扩展规律基本一致,二次老化后再生沥青砂浆的反射裂缝在初期开裂速度加快。

2D-SiC/SiC复合材料的弹丸冲击损伤及冲击后拉伸性能

连续纤维增韧陶瓷基复合材料以其良好的高温性能而被广泛应用在航空发动机等高温部件处,但服役过程中容易受到异物碎片冲击,这受到了广泛关注。研究采用轻气炮对化学气相渗透(CVI)技术制备的2D-SiC/SiC试样进行弹丸冲击,利用高速摄像机记录冲击过程,使用光学显微镜和CT观察异物损伤(FOD)的表面和内部结构,探讨了2D-SiC/SiC复合材料的高速冲击损伤特性。结果表明,2D-SiC/SiC复合材料的高速冲击损伤形式包括锥形裂纹、层间分层、纤维断裂以及基体压溃等。通过表征损伤发现,试件背部损伤和边缘处分层损伤由反射拉伸波造成,随着冲击速度提升,弹丸与拉伸波共同作用会造成试件穿透,试件边缘分层损伤减弱。对高速冲击后的试件进行准静态拉伸试验,明确了剩余力学性能与冲击速度、弹丸直径的关系,表明剩余拉伸强度是表征冲击损伤程度的有效参数。同时,采用数字图像相关(DIC)方法获得拉伸过程中的应变分布,并结合不同弹丸直径、冲击速度冲击后的剩余拉伸强度,进一步对比探究不同变量对冲击损伤的影响。研究结果表明弹丸直径是高速冲击损伤程度的主要影响因素。

内置传感器的沥青混合料变形协调及损伤行为研究

为揭示应变传感器与沥青混合料协同工作性能的演化规律,提高传感器实测数据的应用价值和环境适应性,基于数字图像关联技术和小梁直接拉伸试验,对内置传感器的沥青混合料试件开展多重受力模式下的应变响应研究,分析不同温度条件下传感器与沥青混合料的变形协调性能;并利用四点弯曲试验下的声发射信号和数字图像特征,揭示内置传感器的沥青混合料结构损伤演化规律。研究结果表明:内置应变传感器的沥青混合料变形协调特性与荷载类型、大小及响应时间紧密相关,传感器应变响应具有强烈的温度敏感性,在30~50℃的环境中,传感器应变响应的精准度会急剧衰减,其测量平均绝对误差Eˉa和相对误差Eˉr可分别增大3.49~11.79倍和2.01~2.91倍。利用声发射能量信号准确地刻画了传感器与沥青混合料协同受力下的4阶段损伤演化特征,反映出温度作用会改变结构损伤形式向非稳定开裂的态势发展;不同温度下声发射RA和AF的分布特征表明,内置应变传感器的沥青混合料结构破裂模式受温度影响显著,呈现为拉-剪混合、剪切破裂为主的破裂机制,且随温度不断增大,剪切破裂持续增强,剪切事件由55.7%增长至84.4%,增幅达1.52倍。研究成果对实现内置应变传感器与沥青路面协同工作性能的合理评判,推进传感器技术深度赋能传统沥青路面结构提供参考。

基于X射线CT原位试验的平纹SiC_(f)/SiC压缩损伤演化机理

为揭示陶瓷基复合材料的损伤演化及失效机理,开展了平纹SiC_(f)/SiC复合材料X射线CT原位压缩试验,得到了材料加载过程中和破坏后的CT原位图像数据;采用数字体积相关(DVC)技术获得了材料的位移场和应变场,利用图像处理软件建立复合材料内部三维可视化模型,借助深度学习算法获得纤维束劈裂等损伤的空间分布,进行了压缩损伤演化定性分析以及定量分析.结果表明:在单向压缩过程中,材料在厚度方向出现较大鼓出变形,在宽度方向则发生较小的收缩;厚度方向鼓出变形是引起材料压缩损伤的主要原因.载荷较大时出现表层基体脱落、纤维束劈裂、分层等损伤;纤维束压缩弯折导致材料压缩失效,断口处出现明显V形剪切带.平纹SiC_(f)/SiC的压缩损伤演化分析表明,DVC技术和基于深度学习的图像分割方法可以有效地揭示陶瓷基复合材料压缩损伤演化机理.

A novel indirect optical method for rock stress measurement using microdeformation field analysis

Stress measurement plays a crucial role in geomechanics and rock engineering,especially for the design and construction of large-scale rock projects.This paper presents a novel method,based on the traditional stress relief approach,for indirectly measuring rock stress using optical techniques.The proposed method allows for the acquisition of full-field strain evolution on the borehole’s inner wall before and after disturbance,facilitating the determination of three-dimensional(3D)stress information at multiple points within a single borehole.The study focuses on presenting the method’s theoretical framework,laboratory validation results,and equipment design conception.The theoretical framework comprises three key components:the optical imaging method of the borehole wall,the digital image correlation(DIC)method,and the stress calculation procedure.Laboratory validation tests investigate strain field distribution on the borehole wall under varying stress conditions,with stress results derived from DIC strain data.Remarkably,the optical method demonstrates better measurement accuracy during the unloading stage compared to conventional strain gauge methods.At relatively high stress levels,the optical method demonstrates a relative error of less than 7%and an absolute error within 0.5 MPa.Furthermore,a comparative analysis between the optical method and the conventional contact resistance strain gauge method highlights the optical method’s enhanced accuracy and stability,particularly during the unloading stage.The proposed optical stress measurement device represents a pioneering effort in the application of DIC technology to rock engineering,highlighting its potential to advance stress measurement techniques in the field.

基于DIC技术的固废粒料包裹格栅加筋试验研究

为了控制高速公路改扩建新老路基拼接后的差异沉降,该文针对老路台阶松散、含水率过高,提出一种层状处置结构,即在老路台阶面设置一层固废层包裹格栅,对比了其与砂包裹、掺入消解石灰等措施的处置效果,并采用数字散斑相关技术(DIC)观测加筋影响带,进而确定路基不同层位固废包裹层厚度。进一步分析颗粒旋转与位移情况,验证DIC观测所确定加筋影响带的可靠性与准确性。试验结果表明:①在提高老路台阶筋土界面强度的措施中,效果由优至劣依次为:固废C(粒径为10~20 mm)>固废B(粒径为5~10 mm)>砂>固废A(粒径为1~5 mm)>掺灰6%>掺灰4%,增强效果随包裹固废粒径的增大而提升;②DIC试验结果表明:加筋影响带随法向应力的增大而减小,且格栅上方厚度大于格栅下方,发生旋转的颗粒主要集中在格栅下方3 cm内,格栅上方5 cm内;③基于加筋影响带厚度确定固废包裹层最佳厚度建议值:对于路基中部约为20 cm,路基底部铺设厚度约为15 cm,路基上部铺设层厚度应不小于25 cm。

基于VIC-3D监测的相似材料模拟导水裂隙带发育规律研究

东胜煤田呼吉尔特矿区煤层厚度大、埋深大,煤层开采导水裂隙带存在超高发育现象。为研究呼吉尔特矿区某深埋矿井煤层开采覆岩裂隙的动态演化规律,采用相似材料模拟试验,模拟过程中采用VIC-3D技术监测采动裂隙的动态发育规律。相似材料模拟显示,导水裂隙带发育高度为88 cm,裂采比为30.8,裂隙带形态呈对称“梯形”;VIC-3D监测结果表明,在裂隙发育处,拉张应变较集中,基于VIC-3D监测的导水裂隙带应变云图形态与裂隙带形态相似,与模拟试验结果相吻合,VIC-3D监测技术能够进一步验证实际开挖中裂隙发育情况。

基于DIC技术的曲率对成形极限的影响研究

高强度钢因具有强度高、相同强度下质量更小的特点,成为目前车身及零部件上使用最多的材料。起皱、破裂是汽车覆盖件在弯曲成形及曲面翻边成形过程中的主要缺陷,而曲率是影响其成形性能的重要因素。为了预防起皱、破裂等缺陷,提高高强度钢的成形性能,利用数字图像相关(Digital Image Correlation,DIC)技术及Nakajima试验研究曲率对高强度钢成形极限的影响。以DP780高强度钢为试验材料,分别在不同直径的冲头下对其进行胀形试验,利用DIC技术实时监测板材的应变状态,通过位置相关法求得DP780在不同曲率下的成形极限曲线(Forming Limit Curves,FLC),并绘制各曲率下DP780板材的成形极限图(Forming Limit Diagrams,FLD)。通过对比各曲率下的FLC可知,DP780高强度钢板的成形性能随着曲率的增加而提高。

混凝土粗糙表观对DIC测量误差的影响研究

混凝土构件在长期服役过程中受到风浪、温度应力、腐蚀等外部环境侵蚀,导致混凝土表观粗糙不平。采用数字图像相关技术(DIC)计算力学响应下的混凝土表面应变场时,粗糙表观超过相机景深会引起离焦现象致使散斑退相关,使得DIC测量误差增大。针对此问题,基于3D-DIC系统计算物体表面三维形貌并以Z轴高度极差与平均灰度共同表征混凝土表面粗糙度,结合DIC成像规律与混凝土表面粗糙度的大小预留足够的景深并通过混凝土三点弯实验验证。结果表明:对于粗糙度R_(S)(4.37mm,139)的混凝土,预留景深0.81mm,DIC数据平均偏差高达42%;预留景深4.48mm,DIC数据平均偏差仅12%。

不同温度下掺玄武岩纤维水工沥青混凝土劈裂试验研究

【目的】为了解温度和纤维掺量对水工沥青混凝土抗裂性能的影响,【方法】采用长度6 mm的玄武岩纤维,开展了0℃、5℃、10℃下的掺纤维沥青混凝土巴西劈裂试验,并利用数字图像相关技术(DIC)对试样表面变形进行测量。【结果】结果显示:试验加载初期,试样的水平向变形不明显,当达到峰值荷载后,试样在上下压条之间的直线上出现明显的水平向应变,与裂缝扩展路径相对应,且掺入纤维增加了裂缝扩展路径的曲折程度;相同温度下,沥青混凝土的劈裂抗拉强度随纤维掺量的增加呈先增大后减小的变化趋势,0℃时,掺量0.8%对应的劈裂抗拉强度最大,5℃和10℃时,掺量0.6%对应的劈裂抗拉强度最大;在0℃的低温条件下,掺入0.2%的纤维可提高沥青混凝土的破坏拉伸应变,然而,当温度升高到5℃和10℃时,沥青混凝土的破坏拉伸应变随纤维掺量的增加呈先减小再增大的变化趋势;沥青混凝土断裂能随纤维掺量变化规律同样受温度影响,0℃和10℃时,断裂能随纤维掺量增加而增大,且掺量为0.6%~0.8%时,断裂能最大,但5℃时,断裂能随纤维掺量变化不明显。【结论】结果表明:在不同温度下,掺玄武岩纤维沥青混凝土抗裂性能随纤维掺量的变化规律是不同的。

不同加载速率下的矿岩劈裂破坏特性试验研究

为研究不同加载速率对矿岩劈裂破坏特性的影响,基于数字图像相关(DIC)技术开展矿岩巴西劈裂试验,从抗拉强度、能量演化和水平应变分布等方面分析铁矿石及其围岩在不同加载速率下的劈裂破坏特性。研究结果表明:1)矿岩抗拉强度均随加载速率的增加而增大,其中,围岩抗拉强度随加载速率增大而呈线性增大,而铁矿石抗拉强度先急剧增加后缓慢增加,与加载速率呈幂函数关系。2)随着加载速率增加,矿岩内部总能量和弹性应变能均增大,耗散能则呈下降趋势。加载速率增大后的铁矿石弹性能相比于围岩提升25.78%,岩爆危险性高,合理减缓开采进度可确保矿产开采安全。3)铁矿石和围岩的水平应变随加载速率变化的规律相似,即当加载速率为0.02 kN/s时,铁矿石和围岩应变带从中部向两端延伸,而在高加载速率下,铁矿石和围岩的应变带由两端向圆盘中部汇合;4)不同加载速率变化对矿岩破裂结果的影响不同,当加载速率较低时(0.02 kN/s),矿岩表面水平应变均呈现正态分布,而当加载速率增加后,矿岩端部水平应变突出,且铁矿石相比于围岩更早产生由加载速率变化引起的端部应变集中倾向。

交通荷载作用下堆积层边坡稳定性试验研究

为探究交通荷载下堆积层边坡的破坏模式及抗滑桩的加固效果,通过室内相似试验,开展有抗滑桩和无抗滑桩两组堆积层边坡模型试验,研究了坡体表面不同位置处的加速度响应和坡体内部的动土压力响应以及抗滑桩桩身的弯矩响应规律,并结合DIC技术,研究了交通荷载施加过程中坡面的应变场和运动场情况。试验结果表明:交通荷载作用下,无抗滑桩支护的堆积层边坡堆积体动力响应存在趋高趋表效应,坡顶位置响应最为强烈,因此靠近坡顶位置应作为重点防护位置;堆积层边坡上部最先出现应变集中区域,裂缝形态呈“局部单一”特征,破坏时边坡表面出现张裂和崩塌,裂缝表现出“交错溃散”的特征;抗滑桩支护后堆积层边坡稳定性明显提升,边坡整体性增加,边坡的动态响应更易传递;动力荷载的幅值会影响土压力与加速度的相应幅值,呈正相关,与动力荷载加载点的距离呈负相关。

18CrNiMo7-6合金钢的动态本构参数确定

为了弥补18CrNiMo7-6合金钢动态力学性能及动态本构模型研究的不足,采用MTS伺服疲劳试验机、基于DIC的高温拉伸试验系统以及分离式霍普金森压杆(SHPB)装置,获取了该材料在不同应变率、温度下的应力-应变关系。结果表明:18CrNiMo7-6合金钢具有明显的应变率强化效应和温升软化特性。选用Johnson-Cook(J-C)本构模型描述18CrNiMo7-6合金钢的动态力学性能,基于试验数据,标定了该材料的J-C模型参数,并通过SHPB试验的有限元模拟验证了所得参数的可靠性。以应变硬化项和应变率强化项耦合的形式对J-C本构模型进行修正。修正后的模型与试验数据吻合程度更高,可为实际工程中的数值模拟问题提供参考。

基于数字图像相关技术的混杂纤维混凝土动态抗拉性能试验研究

为研究不同纤维混杂比例下的钢-聚丙烯纤维混凝土(SPFRC)的动态抗拉性能,对六组不同纤维混杂比例的混凝土试件进行动态巴西劈裂试验,借助高速摄像仪和数字图像相关技术(DIC)对各组试样动态拉伸断裂过程进行记录和分析。研究表明:试件的应力时程曲线可以划分为缓速增长、快速增长、稳定、衰减和二次增长五个阶段,相较于素水泥砂浆试件,纤维混凝土试件在应力率二次增长后出现显著的稳定波动平台,纤维混凝土试件的动态拉伸破坏过程具有显著的延性特征;在总纤维掺量保持2%不变的条件下,混杂1%钢纤维与1%聚丙烯纤维的试件具有较优的动态抗拉强度和耗能能力;添加纤维可以减弱试件中心处的拉应变集中现象,混杂1.5%聚丙烯纤维和0.5%钢纤维的试件具有较优的开裂控制能力,平均开裂应变较素水泥砂浆试件提高了2.94倍。