An equivalent target plate damage probability calculation mathematics model and damage evaluation method

Aiming at the requirement of damage testing and evaluation of equivalent target plate based on the explosion of intelligent ammunition, this paper proposes a novel method for damage testing and evaluation method of circumferential equivalent target plate. Leveraging the dispersion characteristics parameters of fragment, we establish a calculation model of the fragment power situation and the damage calculation model under the condition of fragment ultimate penetration equivalent target plate. The damage model of equivalent target plate involves the fragment dispersion density, the local perforation damage criterion, the tearing damage model, and the damage probability. We use the camera to obtain the image of the equivalent target plate with fragment perforation, and research the algorithm of fragment distribution position recognition and fragment perforation area calculation method on the equivalent target plate by image processing technology. Based on the obtained parameters of the breakdown position and perforation area of fragments on equivalent target plate, we apply to damage calculation model of equivalent target plate, and calculate the damage probability of each equivalent target plate, and use the combined probabilistic damage calculation method to obtain the damage evaluation results of the circumferential equivalent target plate in an intelligent ammunition explosion experiment. Through an experimental testing, we verify the feasibility and rationality of the proposed damage evaluation method by comparison, the calculation results can reflect the actual damage effect of the equivalent target plate.

Calculation of the heat flux in the lower divertor target plate using an infrared camera diagnostic system on the experimental advanced superconducting tokamak

During the discharging of Tokamak devices, interactions between the core plasma and plasma-facing components (PFCs) may cause exorbitant heat deposition in the latter. This poses a grave threat to the lifetimes of PFCs materials. An infrared (IR) diagnostic system consisting of an IR camera and an endoscope was installed on an Experimental Advanced Superconducting Tokamak (EAST) to monitor the surface temperature of the lower divertor target plate (LDTP) and to calculate the corresponding heat flux based on its surface temperature and physical structure, via the finite element method. First, the temperature obtained by the IR camera was calibrated against the temperature measured by the built-in thermocouple of EAST under baking conditions to determine the true temperature of the LDTP. Next, based on the finite element method, a target plate model was built and a discretization of the modeling domain was carried out. Then, a heat conduction equation and boundary conditions were determined. Finally, the heat flux was calculated. The new numerical tool provided results similar to those for DFLUX;this is important for future work on related physical processes and heat flux control.

Damage of multi-layer spaced metallic target plates impacted by radial layered PELE

Three different kinds of PELE(the penetrator with lateral efficiency) were launched by ballistic artillery to impact the multi-layer spaced metal target plates.The lmpact velocities of the projectiles were measured by the velocity measuring system.The damage degree and process of each laye r of target plate impacted by the three kinds of projectiles were analyzed.The experimental results show that all the three kinds of projectiles have the effect of expanding holes on the multi-layer spaced metal target plates.For the normal structure PELE(without layered) with tungsten alloy jacket and the radial layered PELE with tungsten alloy jacket,the diameters of holes on the seco nd layer of plates are 3.36 times and 3.76 times of the diameter of the projectile,re spectively.For radial layered PELE with W/Zr-based amorphous composite jacket,due to the large number of tungsten wires dispersed after the impact,the diameter of the holes on the four-layer spaced plates can reach 2.4 times,3.04 times,5.36 times and 2.68 times of the diameter of the projectile.Besides,the normal structure PELE with tungsten alloy jacket and the radial layered PELE whit tungsten alloy jacket formed a large number of fragments impact marks on the third target plate.Although the number of fragments penetrating the third target plate is not as large as that of the normal structure PELE,the area of dispersion of fragments impact craters on the third target plate is larger by the radial layered PELE.The radial layered PELE with W/Zr-based amorphous composite jacket released a lot of heat energy due to the impact of the matrix material,and formed a large area of ablation marks on the last three target plates.

Flow Field and Thermal Analysis of the Divertor Target Plate for HL-2A Tokamak

In the initial phase of the physics experiment, the double-null divertor plates used consist of graphite armor tiles, Mo-alloy intermediate layers and Cu-alloy coolant tubes. In the later operating phase, tungsten will be used as armor tiles. A multi-physical field numerical analysis method is used in this paper. Its analysis model reflects more realistically the real divertor structure than other models. Two-dimensional （2D） and three-dimensional （3D） fluid flow field, temperature distribution and thermal stress analyses of the divertor plates are carried out by the ANSYS code. During the physics experimental phase with a heat flux of 1 MW/m2, a coolant velocity of 5.48 m/s, and a thermal stress of 750 kg/cm2, the graphite armor tiles successfully meet the requirements of temperature, thermal stress and sputtering erosion. The tungsten armor will be considered as a second candidate. The result of simulation can be used for upgrading the design parameters of the HL-2A poloidal divertor.

Approximate Design of Alloy Composition of Cathode Target

An empirical formula for composition demixing analysis in cathodic arc ion plating using alloy target is established based on the concepts of average charged state and relative demixing parameter. The level of composition demixing effect is presented by demixing degree of one element. For binary constituent alloy target, the composition change trend in coating is discussed and the limit of demixing degree for each element is determined. The content of one element with higher average charged state gets larger in coating than in alloy target, at meantime, the content of one element with lower average charged state gets less. For each one of the two constituents, the less the atom percent in alloy target, the larger the difference of its contents between the coating and the target. For triple constituent alloy target, the content change of one element with moderate average charged state is discussed in detail. Its content in coating getting larger or less is determined by the combination result of the contents of the other two elements in alloy target. For a given content of the element with moderate average charged state in triple alloy target, the content deviation level of that element from coating to alloy target will be not larger than that using binary alloy target containing only that element and one of the two others. According to the wanted coating composition, the composition design of alloy target is easily deduced from the formula.

An enhanced oil recovery technique by targeted delivery ASP flooding

Aiming at the problem of the loss of the ASP flooding near the injection wells, this paper gives a new idea to enhance oil recovery called "Technique of Targeted Delivery", which combines the radial horizontal well with ultra-short radius drilled by high pressure water jet with the ASP flooding, the horizontal wells work as the "Target channel" transport the ternary composite system to the remaining oil enrichment area directly, to avoid the loss of the ternary composite system near the injection wells. The plate homogeneous experiment and numerical simulation show that the technique can significantly improve the sweep efficiency and the effect of the oil displacement, and greatly improve the oil recovery rate. The optimal flooding parameters of the target transport technique are: the right angle target, the length of the channel is about 15% of the well distance and the injection volume of the ternary composite system is 0.4 PV. Under such conditions, this technique can enhance recovery by 48.87% and 22.04% respectively, compared with the water flooding and conventional ASP flooding. The target transport technique solves the problem of high loss of chemical agent in near-wellbore area during the ASP flooding, and compensates for the high cost of ASP flooding and the limitation of application, and has a broad application prospect.

基于YOLOv8-OCR的井下人员检测算法

为提高井下昏暗环境的目标检测性能,将行人属性应用到井下,将反光号码牌贴在安全帽和工作服上作为属性进行识别。针对井下小目标检测率低的缺点,提出了一种将YOLOv8检测算法与光学字符识别(Optical Character Recognation, OCR)技术相结合的方法。通过添加卷积块注意力模块(Convolutional Block Attention Module, CBAM),提高了网络对不同尺度的特征提取能力;将YOLOv8中的CBS模块改进为CBF模块,提高了目标的识别准确率;对检测到的反光号码牌区域用OCR技术对区域内数字进行识别,进一步提高了模型的检测精度。实验结果表明,提出的方法在自建数据集上获得了93.2%的识别准确率和每张24.4 ms的检测速度,相比YOLOv8模型有着更高的准确率,能够有效地应对井下环境中的光照变化和干扰因素并且满足实时检测的要求。

全尺寸圆锥-球缺组合药型罩聚能战斗部毁伤试验

为提升聚能战斗部毁伤性能,基于圆锥-球缺组合药型罩战斗部的起爆机理,设计并加工一种全尺寸圆锥-球缺组合药型罩聚能战斗部及含水夹层结构靶板,进行战斗部对靶板的水下爆炸毁伤试验。试验结果表明:该聚能战斗部能够完全穿透10 mm非耐压壳体+1000 mm中间水层+40 mm耐压壳体靶板的含水夹层结构靶板,并对后效靶板的穿甲深度达到130 mm以上。该组合药型罩结构有利于提升战斗部对含水夹层目标的毁伤效果,对于提升战斗部威力提供了有效的途径。

圆锥-球缺组合药型罩战斗部侵彻双层水间隔靶板

为提升聚能战斗部毁伤性能,基于组合药型罩战斗部的起爆机理,设计一种圆锥-球缺组合药型罩聚能战斗部及双层水间隔靶板结构,建立该战斗部侵彻双层水间隔靶板的物理模型,进行数值模拟计算,根据计算结果加工战斗部及靶板的1∶3缩比模型样机,展开相应试验,为设计全尺寸战斗部样机奠定了基础。试验结果表明:该战斗部侵彻含水夹层目标时具有独特的优势,对目标的破坏效应显著增强。

基于顶点与主体区域同步检测的精准车牌定位

为应对非约束环境下的车牌精定位问题,提出一种基于顶点局部区域与主体区域同步检测策略的非约束性车牌定位算法。通过删减YOLOv5网络的输出结构,训练得到可同步检测车牌及顶点区域的车牌检测网络,在兼顾精度与计算速度的前提下,实现车牌顶点和主体区域的同步定位。针对一幅图中存在多个车牌区域及顶点区域存在少量漏检和误检的情况,分别设计了车牌顶点归类和单一缺失顶点预测后处理算法,借助顶点间的空间位置关系进行漏检目标预测和误检目标排查,有效改善了因场景复杂导致的个别顶点目标检测效果差的问题。所提算法在中国城市停车场数据集(CCPD)上的测试结果显示,平均精准率达99.25%,平均召回率达98.70%。所提算法不仅能够准确预测出车牌的4个顶点坐标,而且在中端GPU硬件平台上处理速度可达121帧/s,具有较好的应用价值。

核聚变装置偏滤器靶板材料选择与研究进展

可控热核聚变能是人类最理想的清洁能源之一,是解决人类能源和环境问题的根本途径。目前,可控热核聚变能的发展面临诸多挑战,偏滤器靶板作为磁约束核聚变装置中的重要部件,其设计和制造是维持等离子体放电、实现核聚变反应堆稳定运行亟需解决的关键问题之一。作为等离子体轰击最严重区域,偏滤器靶板经受着高能粒子流辐照和高热负荷冲击(10 MW·m^(-2)稳态负荷和20 MW·m^(-2)瞬态负荷),同时承担着磁约束聚变装置最主要的排热功能。因此,研发具有优异性能的靶板材料是推动核聚变能发展的关键一步。目前,金属铍、碳基材料以及钨基材料是主要的3种偏滤器靶板候选材料。基于国内外现有研究成果,论述了偏滤器靶板材料的选择与研究进展,对比分析了3种候选材料的优势以及存在的问题,以期为偏滤器靶板材料的选择、研发提供借鉴。

低阻叉流板式换热器传热性能与热阻靶向调控研究

用于烟气余热回收的板式换热器存在温度分布不均的问题。为改善烟气温度分布均匀性,有效遏制换热器腐蚀,本文通过实验测试对比碳钢与铸铁材质低阻叉流板式换热器性能差异,运用数值仿真预测局部流动传热特性并开展热阻分析,采用局部热阻调控方法设计了非均匀翅片结构。实验结果表明,在450℃高温时碳钢与铸铁材质的叉流板式换热器总传热系数分别达到32.5 W/(m^(2)·K)与25.1 W/(m^(2)·K)。通过数值仿真研究发现,叉流传热方式导致烟气侧沿程截面温度分布极不均匀,在热侧出口与冷侧入口交叉区、热侧出口与冷侧出口交叉区的热阻大,极易导致局部烟气温度低于露点温度。基于热阻分析法开发非均匀翅片结构,实施局部热阻靶向调控,最终实现维持阻力几乎不变情况下,使出口截面平均温度方差由6.9℃降至1.1℃,换热器内流体温度分布均匀性得到显著提升。

爆炸荷载下背爆面柔性聚脲防护混凝土靶板的反直观行为

金属结构在冲击载荷作用下,最终的变形方向与加载的方向相反,这一现象被称为反直观行为,试验发现背爆面柔性聚脲防护混凝土靶板在75 g TNT爆炸荷载下也发生了反直观行为。为了研究背爆面柔性聚脲防护混凝土靶板在爆炸荷载下的反直观行为,采用ANSYS/LSDYNA有限元软件,建立了背爆面柔性聚脲防护混凝土靶板在爆炸荷载作用下的有限元模型。利用有限元模型分析背爆面柔性聚脲防护混凝土靶板的动态响应规律,从能量的角度研究靶板反直观行为的发生机理。以靶板的中心点位移和挠度为指标,参数化分析了炸药药量和聚脲涂层厚度对靶板反直观行为的影响规律。结果表明:靶板的反直观行为是由聚脲涂层的应变能释放、混凝土损伤破坏的能量耗散及两种材料间能量的相互转化这三种因素共同作用导致的;炸药药量是反直观行为能否发生的关键因素,当药量较低或较高时,靶板都无法发生反直观行为;涂层厚度在2~8 mm范围内,靶板均出现了反直观行为,其弯曲程度随着涂层厚度的增加先增大后减小。

层叠型缓冲靶板对弹载测试仪的保护作用研究

使用空气炮模拟火炮发射时的高过载环境对弹载测试仪进行测试时,弹丸撞击靶板会产生尖峰脉冲对测试仪造成严重的损伤,为提高测试仪的存活性,展开对缓冲靶板层叠方式(不同材质的靶板相互叠加的叠层结构)的研究。通过撞击动力学理论描述弹丸对靶板的压缩和侵彻行为,并结合动量守恒和能量守恒定律计算出靶板参数和传递到靶板上的冲量的关系。使用ANSYS/LS-DYNA建立弹丸正侵彻靶板模型,弹丸速度为200 m/s、质量为5.5 kg,仿真结果表明:3层总厚度450 mm的泡沫铝+泡沫铝+橡胶组合方式能有效消除尖峰脉冲并缩短弹丸对靶板的作用时间,加速度均值约为7 000g,脉宽为2.8 ms。受条件限制,空气炮试验采用弹丸质量为5.5 kg、速度为150 m/s,并将缓冲靶板的单层厚度减小到100 mm,结果表明:在泡沫铝+泡沫铝+橡胶组合方式下,弹丸结构和测试仪功能完好,加速度均值约为27 000g,脉宽为0.55 ms。

基于深度学习神经网络的水中爆炸靶板变形响应预测研究

水中爆炸靶板变形表现为结构与流体在冲击波作用下的复杂非线性耦合作用。文中通过设计和优化深度学习神经网络以预测输出不同靶板厚度、冲击因子、爆炸药量和爆炸距离条件下的靶板动态变形位移数据,测试集预测的决定系数和准确率达到0.99和0.95。与25个仿真工况数据相比,基于预测模型得到的9261个工况数据形成的爆炸变形响应分析图能够覆盖更细致的特征参数范围和最大变形量变化趋势,可为水中武器设计及水下防护应用提供重要参考依据。

不同金属镀层单晶硅靶板的冲击受力特性

为了探究金属镀层对单晶硅靶板抗冲击性能的影响,建立了金属/单晶硅复合靶板理论分析模型,分析讨论了单晶硅靶板表面的最大应力与镀层材料动态屈服应力的关系,应用有限元法在LS-DYNA软件中对金属/单晶硅复合靶板进行瞬态动力学计算,得到了不同金属镀层单晶硅靶板冲击受力后的力学响应。根据实验结果总结得到金属镀层对单晶硅靶板冲击受力具有一定的抗冲击效果,能够延迟和减弱出现在靶板正、背面的应力峰值,减小在靶板上产生的应力。

不同基底氘钛靶性能研究

中子发生器的靶片性能影响中子产额和稳定性。为防止钛膜和基底材料间生成合金,进而影响靶片性能,本研究在氘钛靶储氢层与基底层之间采用了镀金工艺,以阻止钛膜和靶片的基底材料相互渗透,进而影响钛膜中钛元素浓度,造成靶上有效氘浓度降低。经过对比测试,钼基底镀金氘钛靶的中子产额可达到1.61×10^(9)s^(−1),在束流强度一定的条件下,其中子产额及稳定性优于铜基底镀金氘钛靶和纯钼基底氘钛靶。电子显微镜能谱分析显示,钼基底镀金氘钛靶中钛元素丰度最高,成功解释了其中子产额较高的原因。同时模拟计算排除了实验中靶片温度上升对靶中氘溢出的影响。此研究为理解和优化中子发生器提供了有价值的见解。

Soret和Dufour效应耦合对HL-2A偏滤器靶板氘浓度与温度双扩散的影响

在L/H模放电情况下,考虑Soret和Dufour效应耦合影响,用JD-CF程序研究了HL-2A偏滤器靶板中氘粒子浓度、温度、滞留量随时间变化影响。结果表明,在L/H模放电下,Soret和Dufour效应会对不同靶板材料(RAFM钢/钨)内不同位置处氘浓度分布、温度分布、氘滞留量产生一定影响,其最大变化率约为10%。在H模放电下Soret和Dufour效应对靶板的影响比在L模放电下的更明显,且对RAFM钢的影响比对钨的更明显。该研究结果对研究边缘等离子体输运、聚变堆燃料再循环、氚的滞留及投料量有一定参考价值。

静态爆轰试验后带破片穿孔靶板形变恢复方法

针对静态爆轰试验后发生形变的靶板,提出一种新的参数化方法,在三角网格模型下解决了靶板上孔洞部分参数化形变大以及边界角度形变、面积形变和拉伸形变大的问题。该方法首先通过拟合变分隐式曲面修补孔洞,接着采用基于虚拟边界的ABF++方法进行参数化,然后根据试验前靶板的网格能量,优化整体的靶板点云,进一步减少形变,最后去除附加的修补点和虚拟边界点,得到参数化后的靶板点云。实验选取了LSCM、ABF++方法来直接对两个经典人脸三角网格模型和靶板三角网格模型及其对应带孔洞的模型进行形变恢复,并与所提方法进行了对比,实验结果表明所提方法在三个模型的外边界角度畸变、外边界面积畸变,含孔洞三个模型的内边界角度畸变、内边界面积畸变,四项指标上相较于LSCM和ABF++平均降低了31.10%、23.76%、19.60%、10.08%,因此可以更好地减少参数化曲面上的内外边界形变,为带破片穿孔的靶板提供一种有效的参数化方法。

结构间隙对复合靶板抗弹性能的影响

为研究结构间隙对复合靶板抗弹性能的影响,探究弹体与靶板的响应规律,利用有限元软件对4种不同间隙结构的复合靶板在不同弹速冲击下的毁伤变形状态进行仿真分析,得到弹体的剩余速度和靶板各组成部分吸能占比的变化规律。结果表明:结构间隙会影响复合靶板的抗弹性能,在弹体速度相同的情况下,有结构间隙靶板的弹体剩余速度更小;在不同速度段,结构间隙布置在不同位置时发挥的作用是不同的;抗弹芯层在弹体侵彻过程中是吸收弹体动能的主要部分,吸能占比约为58%;靶板间结构间隙能提升靶板的抗弹性能。