Automatic Monitoring System for 3-D Deformation of Crustal Fault Based on Laser and Machine Vision

An automatic monitoring method of the 3-D deformation is presented for crustal fault based on laser and machine vision. The laser source and screen are independently set up in the headwall and footwall, the collimated laser beam creates a circular spot on the screen, meanwhile, the industrial camera captures the tiny deformation of the crustal fault by monitoring the change of the spot position. This method significantly reduces the cost of equipment and labor, provides daily sampling to ensure high continuity of data. A prototype of the automatic monitoring system is developed, and a repeatability test indicates that the error of spot jitter can be minimized by consecutive samples. Meanwhile, the environmental correction model is determined to ensure that environmental changes do not disturb the system. Furthermore, the automatic monitoring system has been applied at the deformation monitoring station(KJX02) of China Beishan underground research laboratory, where continuous deformation monitoring is underway.

Investigation of Surface Integrity on TC17 Titanium Alloy Treated by Square-spot Laser Shock Peening

Laser shock peening（LSP） is an innovative surface treatment method,which has been shown to greatly improve the fatigue life of many metallic components.This work investigates surface integrity of TC17 titanium alloy treated by LSP with innovative square laser spot.Nd：glass laser with duration of 30 ns and spot size of 4 mm×4 mm is applied.The surface morphology and surface residual stress of the TC17 titanium alloy,treated with varying peening parameters such as laser power density and overlapping ratio,have been studied in detail.The results show that laser pulse energy greatly influences surface morphology and surface residual stress around single-spot treated areas,and compressive residual stresses are saturated as laser pulse energy is over 55 J.There are significantly different surface morphologies and residual stress distributions at the overlapped areas with different overlapping ratios.A relative smooth surface is produced with uniform compressive residual stress distribution at an overlapping ratio of 8 %.The experiment of residual stress relaxation is implemented by measuring residual stress at the center of four overlapped spots and by four point bending fatigue test at the frequency of 105 Hz.The compressive residual stresses induced by LSP are found to relax quite slowly under cyclic fatigue loading.

Visual sensing and morphological image processing of weld pool in laser spot welding

A visual sensing system was established to monitor the weld pool in laser spot welding. The top-hat and bottom-hat transformation algorithms based on mathematical morphology were used to compensate for non-uniform contrast of weld pool edge. Moreover, the canny edge detector was applied to extract the weld paol profile. The edge detected results show that the morphological operation is obviously superior to the traditional contrast enhancement method. In addition, the combination of dilation and erosion was applied to eliminate the irrelevant edge details, and the smooth weld pool edge was acquired. Based on the image processing technology described above, the dynamic process of weld pool diameter during laser spot welding was obtained.

Surface crack imaging based on delayed temperature difference at symmetric points by laser spot thermography

Laser spot thermography is a novel technique for the detection of surface cracks with a laser to heat sample locally and with an IR camera to record the surface temperature distribution. Common methods to characterize cracks are only suitable for the situation that the laser scanning path is vertical to the crack. But due to the randomness of cracks,when the scanning path is parallel to the crack,surface cracks cannot be detected by these methods. To tackle this problem,a method is presented which is suitable for the situation that the scanning path is parallel to crack. The main idea is to evaluate the crack-caused asymmetries of the surface temperature distribution. The effect of temperature gradient and the maximum scanning interval are analyzed by a 2D simulation. A new crack imaging technique is presented that is based on delayed temperature difference at symmetric points to characterize the crack in the thermal image. Compared well with those obtained by the spatial first derivative method,experimental results are shown to efficiently prove this method.

Numerical simulation of residual stress field induced by laser shock processing with square spot

Laser shock processing（LSP）,also known as laser peening,is a novel surface treatment technique in the past few years.Compressive residual stresses which imparted by LSP are very important for improving fatigue,corrosion and wea rresistance of metals.Finite element analysis（FEA） simulation using ABAQUS software has been applied to predict residualstresses induced by LSP on Ti-6Al-4V titanium alloy with laser pulse duration 30 ns and water confined ablation mode.The residual stress field generated by different shape laser spots was studied,and the square laser spot is shown the most suitability for avoiding stress lack phenomenon and overlapping LSP.Surface residual stresses and plastically affected depth within single square spot both increased with the increase of laser intensity and laser shock times.Furthermore,compared with circle and ellipse spot,the residual stress distribution in overlapping square spots is very uniform only with small overlapping ratio.LSP with square spot can process advantageous residual stress field,and this technique will be used widely.

激光剥蚀电感耦合等离子体质谱法微区原位定量分析锂铍矿物化学成分

锂、铍是当前全球战略性关键金属,采用激光剥蚀电感耦合等离子体质谱(LA-ICP-MS)建立分析方法可以实现微区原位定量分析天然矿物样品中的锂、铍元素含量,为锂铍资源高效利用以及赋存状态的研究提供分析技术支撑。锂辉石和绿柱石等矿物是提取锂、铍元素的主要原料,微区分析常用的电子探针方法对于能量较低的轻元素难以准确定量,而LA-ICP-MS方法亟待改进降低非基体匹配校准带来的基体效应提高分析的准确度和精密度。本文探讨了仪器工作条件(同位素选择及计数模式、载气He气流速、样品气Ar气流速、束斑直径、能量密度大小)和数据处理方法(外部标准物质、内标元素)对定量结果精密度和准确度的影响。实验结果表明:He和Ar气体流速不仅会影响锂、铍信号强度,而且适当降低载气He流速(0.6L/min)可以减小相对误差。增加束斑直径虽可以将数据精密度提高10%以上,但是对于准确度影响不大;对于绿柱石这类硬度高的透明矿物应提高能量密度(相对强度>75%,通量>2.7J/cm^(2))以保证产生稳定剥蚀信号。测定7Li时选择现有标准物质中含量较高的GSE-1G校准、9Be选择NIST610校准,以Al作为内标补偿元素,计算结果相对误差较小。LA-ICP-MS方法通过调整仪器工作条件和数据处理方法,可以降低基体差异,提高数据准确度,解决微区原位准确定量分析锂、铍轻元素的难题,为锂、铍资源的勘探开发和高效利用提供有力的技术支撑。但是也亟待开发高锂、铍含量的微区标准物质,解决因现有标准物质与样品中含量差异造成的基体效应来进一步提高数据质量。

多路激光集束的焦斑测试技术

为了实现多路激光集束焦斑测量,给出其时间和空间分辨的特性,搭建了基于成像系统、光电管结合示波器、条纹相机和科学CCD等主要部件组成的焦斑光学测试平台。实验之前,对科学CCD的灵敏度和动态范围及条纹相机增益系数、狭缝宽度、扫描时间等性能参数进行离线测试标定。采用CCD测试多路激光时间积分的集束焦斑空间分布;采用光电管结合示波器及条纹相机对多路激光到达靶点的时间同步进行测试;开展高质量集束焦斑的时间分辨特性测试,获得了光谱色散匀滑光束焦斑精细的时空演化图像。多路激光集束焦斑形态及多路光束时间同步测试为提升高功率激光装置焦斑测试技术和方法提供了支撑。

基于视觉传达技术的激光光斑图像超分辨率重建方法

激光光斑图像在成像过程中易受到成像条件和成像方式的限制,导致激光光斑图像的分辨率比较低,难以满足实际需求。为此,提出基于视觉传达技术的激光光斑图像超分辨率重建方法。采用视觉传达技术采集激光光斑图像,并使用双树复小波阈值方法对激光光斑图像去噪处理,通过改进稠密神经网络提取激光光斑图像特征,基于奇异值分解方法降低字典中原子的数目,改进稀疏表达正则化方法,实现激光光斑图像的超分辨率重建。实验结果表明,所提方法的低分辨率图像重建结果与原始图像更加接近,重建图像的结构相似度均在0.9以上,证明该方法的重建效果好、更适合实际应用。

复杂光线环境下星载激光光斑图像特征参数提取

星载激光光斑图像易受采集时复杂光线背景的影响,导致激光光斑特征参数提取精度不佳,由此提出复杂光线环境下星载激光光斑图像特征参数提取方法。首先,基于光照校正的Retinex图像增强算法光照补偿及增强星载激光光斑图像,以消除复杂光线环境的影响;其次,基于二次阈值分割与形态学消噪结合方法提取光斑边界;最后,使用一阶灰度重心法与椭圆拟合结合方法完成激光光斑图像特征参数提取。仿真结果表明,所提方法的星载激光光斑图像特征参数提取精度保持在95%以上,具有较好的提取性能。

激光束光斑漂移反演大气湍流各向异性实验研究

设计了两束正交激光束光斑漂移的实时影像记录系统,进行了一系列的激光束大气传输外场实验,对比研究大气湍流环境下两正交方向激光束的光斑漂移,反演研究大气湍流的各向异性。实验结果表明,近地面大气湍流具有各向异性且表现为:一、与风向相关,当激光传输路径与风向夹角很小时,其垂直和水平方向的光斑漂移量会出现较大的差异,当激光传输路径与风向正交时,其垂直和水平方向光斑漂移量基本一致。二、与实时气温相关,表现为两正交激光束的光斑漂移量统计值在垂直和水平方向的四个分量中的不均匀分配,且气温降低会使不均匀分配的强度增加。分析研究成果,本文提出大气湍流各向异性强度指数A的概念,该指数的大小可以综合性的表征大气湍流各向异性特征及其强度。

一种新型抗畸变激光光斑检测算法研究

为了研究大坝内部的沉降和水平位移,设计了一种精密的微位移测量装置。其中,基于二维图像处理的激光光斑位移检测算法为该装置重要的组成部分。本文提出了一种抗畸变激光光斑中心检测算法,通过对原始光斑进行阈值分割,得出光斑发散部分的图像,并通过闭操作和高斯滤波对之进行降噪和平滑。然后,用sobel算子对其进行边缘检测,从而得出较为光滑的边缘轮廓。最后,对其进行抗畸变激光光斑中心检测算法的处理,确定光斑中心。同时,又通过实验装置来采集一系列激光光斑图像,并用传统激光光斑中心检测算法和抗畸变激光光斑中心检测算法对其进行了处理并进行比较。结果表明,抗畸变激光光斑中心检测算法精度最高,有效消除了远距离光斑的畸变对光斑中心计算的影响。

基于稀疏表示的激光光斑复原方法

使用探测器阵列对远场激光光斑分布进行测量,是目前评价激光大气传输特性以及激光发射系统性能的重要方法。利用阵列探测器对高能激光系统性能进行评估,需要准确复原探测器测量所得的激光远场光斑。介绍了一种基于字典学习的阵列探测器激光光斑复原方法。首先利用改进后的线性插值算法对原始低采样光斑进行插值,其次介绍了K-SVD(K-singular value decomposition)字典学习算法,将所提方法运用到插值后的图像复原中。此外,用峰值信噪比(peak signal-to-noise ratio,PSNR)和光斑质心偏移量对复原图像进行量化对比。该算法复原的图像PSNR比传统算法高出4 dB~5 dB,光斑质心偏差量在x轴和y轴方向与传统算法相比分别降低了14.7%和12.2%。实验结果表明,所提方法在视觉和量化指标上都取得了良好的光斑图像复原效果。

存在旋转圆跳动的轧辊表面的送丝激光熔覆工艺研究

为解决轧辊旋转时产生的圆跳动影响送丝激光熔覆轧辊修复的问题,对轧辊旋转圆跳动对于丝材尖端与轧辊面位置及激光熔覆过程的影响规律进行理论分析,并针对激光功率和光斑直径对存在圆跳动的轧辊激光熔覆修复工艺的影响进行试验研究。研究结果表明:在熔覆过程中,由于圆跳动的影响,前沿送丝成形的熔覆道高度过低,后沿送丝成形的熔覆道易出现大量毛刺,但中间送丝成形的熔覆道表面形貌相对较好;在小光斑、低功率工艺状况下,中间送丝成形的熔覆道也会出现孔隙以及毛刺,增加激光功率和光斑直径可以减少此现象。在圆跳动误差不大于0.6 mm情况下,当激光功率P为2 400 W、指示红光直径为6.5 mm时,几乎不会出现缺陷。采用小搭接率进行多道搭接试验时,圆跳动会影响第1道熔覆道的实际成形位置,搭接率为40%时成形的熔覆道受影响不明显。

光斑形状对BBO晶体四倍频效率的影响

BBO晶体是一种被广泛应用于激光倍频、混频、光参量振荡等光学领域的非线性频率变换晶体。但是由于该晶体在四倍频过程中具有较大的走离角,会使产生的倍频光与基频光逐渐分开,降低了四倍频转换效率。文章模拟了在532~266nm倍频过程中,入射光斑形状为圆形和矩形时对BBO晶体四倍频效率的影响。计算结果表明,采用矩形光斑入射到BBO晶体表面可以延长有效倍频孔径长度,减小走离效应对倍频光的影响,明显提升四倍频效率。

激光熔覆光斑形状对铁基涂层组织结构及耐磨性能的影响研究

采用线光斑激光熔覆技术和圆光斑激光熔覆技术在热作模具钢H13钢上制备铁基耐磨涂层,使用XRD、SEM、EDS等对比研究不同光斑形状对铁基涂层的熔覆效率、成分物相、组织结构和耐磨性能的影响。结果表明:采用圆光斑激光熔覆技术和线光斑激光熔覆技术制备的涂层皆为无缺陷涂层,由于线光斑激光熔覆技术具有更大的光斑面积、更快的扫描速度,使得线光斑激光熔覆涂层的熔覆效率是圆光斑激光熔覆涂层的4.4倍,稀释率更小,约为圆光斑激光熔覆涂层的1/5。因为圆光斑的线能量比线光斑的线能量大,导致圆光斑激光熔覆涂层中的马氏体和碳化物的含量高于线光斑激光熔覆涂层中马氏体和碳化物的含量,圆光斑激光熔覆涂层的硬度和耐磨性高于线光斑激光熔覆涂层。

线光斑激光熔覆Ni-Al金属间化合物工艺及组织研究

为了提高P92钢的耐高温氧化性能,采用线光斑在P92钢基体表面激光熔覆Ni-Al金属间化合物,对熔覆工艺参数进行了筛选,并对试样的组织形貌和成份进行了分析。结果表明,在筛选后的熔覆工艺下试样熔覆层未发现裂纹,无开裂倾向;P92钢基体熔化较少,基体中Fe元素扩散至顶部含量不到5%,熔覆层中主要物相为Ni3Al和NiAl,熔覆层顶部至基体部分的显微组织由等轴晶向树枝晶、柱状晶和平面晶转变。当激光功率1 800 W、扫描速度2 m/min、送粉速度为17 r/min、送粉气流量为8 L/min时,可以减少基体熔化和Fe元素扩散,从而对解决激光熔覆时Ni-Al金属间化合物熔覆层开裂、钢基体中Fe元素扩散问题提供了思路。

激光功率对3/4H SUS301和SUS316异种不锈钢激光点焊成形特征及组织性能的影响

采用准连续激光器对测力传感器的3/4H SUS301弹性体和SUS316支撑体进行异种不锈钢激光焊接,探讨了激光功率对点焊接头成形特征和力学性能的影响。研究表明,采用准连续激光模式,在脉冲时间为2 ms、激光功率为180 W至270 W范围内,弹性体焊后的角变形量随着激光功率的增大而增大,激光功率为270 W时弹性体焊后的角变形远低于传感器容许的变形量。当激光功率为210W时,在焊接界面处产生气孔缺陷,焊接功率增大至270 W时,在匙孔底部形成严重的气孔缺陷。焊缝内部以胞状晶方式生长,从熔合区两侧向焊缝中心生长为粗大的柱状晶,焊缝中心为等轴状的树枝晶,随着激光功率的增大,等轴晶区域的宽度减小。焊缝区承受较高的焊接热量使得焊缝区内形变组织发生不完全再结晶,致使形变诱发马氏体相变被抑制,α'马氏体含量降低。点焊接头的剪切力随着激光功率先增大后减小,当激光功率为250 W时,接头的剪切力达到最大值0.49 kN,远高于行业要求。

2A12铝合金方形光斑激光冲击强化残余应力场研究

为了分析以2A12铝合金为代表的航天铝合金在激光冲击强化后表面和内部残余应力的分布,采用数值模拟的方法对2A12铝合金进行了方光斑激光冲击强化后的残余应力场计算,得到了不同激光参数下的残余应力场分布曲线。研究发现,在脉冲宽度为10 ns、光斑尺寸为4 mm的固定参数下,单光斑激光冲击强化在峰值压力为1800 MPa时残余应力分布最优,最大残余应力值为-242.1 MPa。冲击强化两次获得了最佳残余应力分布,其残余应力最大值为-403.8 MPa。此外,在多光斑激光冲击强化中,利用60%的光斑重叠率可以在表面和深度方向上产生最佳的残余应力分布。本模型模拟结果与已有实验数据吻合较好,可为实际方形光斑激光冲击强化铝合金实验提供理论指导。

焊接速度及芯环比对热成形钢双光斑激光焊接接头组织与性能的影响

目的研究焊接速度和芯环比对PHS2000热成形钢双光斑激光焊接接头组织与性能的影响。方法使用光学显微镜(OM)、扫描电子显微镜(SEM)等分析了不同参数下焊接接头的组织演变过程,并对焊接接头的抗拉强度和显微硬度进行了测量对比。结果随着焊接速度的增大,焊缝区(Weld Zone,WZ)平均晶粒尺寸由12.33μm逐渐减小至10.52μm。热影响区(HeatAffectedZone,HAZ)平均晶粒尺寸由11.37μm逐渐减小至9.12μm。随着芯环比的提高,WZ平均晶粒尺寸由11.13μm增加至12.62μm;其中,当芯环比为65%时,HAZ平均晶粒尺寸最小,为9.66μm。随着焊接速度和芯环比的提高,焊接接头处的抗拉强度大致呈先上升后下降的趋势。当焊接速度为150mm/min和芯环比为65%时,焊缝区的显微硬度普遍高于其他参数下焊缝区的显微硬度。结论与芯环比相比,焊接速度对焊接接头组织和力学性能的影响较大;在固定激光功率为4100 W、离焦量为–2 mm的情况下,当焊接速度为150 mm/min、芯环比为65%时,焊接接头的抗拉强度最优,达到1715MPa。

CFRP厚度激光超声脉冲反射测试及工艺优化

为了提高碳纤维复合材料CFRP的厚度测试精度,设计了一种基于激光超声脉冲反射法的CFRP厚度测试方法,并进行工艺参数优化。研究结果表明:以凸透镜进行厚度测试时,可以达到5.2%以内的相对误差。提高光斑外径后,形成了更低幅值的超声波信号。凸透镜聚焦形成的光斑面积比柱面透镜聚集形成的光斑面积更小,提高了能量密度,促进了更大幅值超声信号被激发,显著增强激光热弹效果。不存在外部光源的情况下,形成了具有稳定频率的反射信号。当光源功率提高后,信号中产生了更大噪声频率与幅值;背景噪声对多次反射回波也造成了淹没。功率0.45mW与0.60mW时,信号相对有效信号频率更大,对反射信号也造成明显影响。该研究可以拓宽到其它微观材料的厚度检测领域,具有很好的精度控制标准。