Research on the quasi-isentropic driving model of aluminized explosives in the detonation wave propagation direction

Taking CL-20(Hexanitrohexaazaisowurtzitane)-based aluminized explosives with high gurney energy as the research object, this research experimentally investigates the work capability of different aluminized explosive formulations when driving metal flyer plates in the denotation wave propagation direction.The research results showed that the formulations with 43 μm aluminum(Al) powder particles(The particle sizes of Al powder were in the range of 2~43 μm) exhibited the optimal performance in driving flyer plates along the denotation wave propagation direction. Compared to the formulations with Al powder 13 μm, the formulations with Al powder 2 μm delivered better performance in accelerating metal flyer plates in the early stage, which, however, turned to be poor in the later stage. The CL-20-based explosives containing 25% Al far under-performed those containing 15% Al. Based on the proposed quasi-isentropic hypothesis, relevant isentropy theories, and the functional relationship between detonation parameters and entropy as well as Al reaction degree, the characteristic lines of aluminized explosives in accelerating flyer plates were theoretically studied, a quasi-isentropic theoretical model for the aluminized explosive driving the flyer plate was built and the calculation methods for the variations of flyer plate velocity, Al reaction degree, and detonation product parameters with time and axial positions were developed. The theoretical model built is verified by the experimental results of the CL-20-based aluminized explosive driving flyer plate. It was found that the model built could accurately calculate the variations of flyer plate velocity and Al reaction degree over time. In addition, how physical parameters including detonation product pressure and temperature varied with time and axial positions was identified. The action time of the positive pressure after the detonation of aluminized explosives was found prolonged and the downtrend of the temperature was slowed down and even reversed to a slight rise due to the aftereffect reaction between the Al powder and the detonation products.

超音速等离子喷涂Al-35Si-4Fe涂层制备工艺优化及摩擦学性能

为改善铝硅合金的摩擦学性能,以YL113铝硅合金为基体,喷涂功率、总气流量和喷涂距离为试验因素,显微硬度和孔隙率为考核指标,采用三因素三水平的正交试验法得到了超音速等离子喷涂Al-35Si-4Fe涂层的最佳制备工艺;研究了此工艺下涂层的摩擦学性能。结果表明:在喷涂功率65 kW,总气流量110 L min,喷涂距离95 mm时,涂层质量最佳,Al-35Si-4Fe涂层的显微硬度达到(465±24.4)HV_(0.2),涂层孔隙率为1.3%。试验条件下,Al-35Si-4Fe涂层的磨损机制以疲劳磨损为主,磨粒磨损为辅。Al-35Si-4Fe涂层的磨损率为1.88×10^(-4) mm^(3)(N·m),摩擦因数为0.37。优化后的Al-35Si-4Fe涂层能有效保护内部YL113铝硅合金,延长其使用寿命,并应对更加复杂的工况。

Au-Al键合界面金属间化合物对可靠性影响的研究

引线键合工艺是半导体封装过程中十分重要的一道工序,键合质量的提高基于键合可靠性的提升,而键合界面对键合的可靠性,乃至对电子元器件的服役性能和使用寿命都有着极大的影响。但是,在键合完成初期,由于会形成少量的金属间化合物(IMC)。而且,随着时间的增加和温度的升高,金属间化合物会增加。金属间化合物过多时易导致键合强度降低、变脆,以及接触电阻变大等问题,应该看到,脆性的金属间化合物会使键合点在受周期性应力作用时引发疲劳破坏,最终可导致器件开路或器件的电性能退化。其中,金属间化合物的形成和可肯达尔(Kirkendall)空洞是金铝(Au-Al)键合失效的主要失效机理。本文结合充分的实验测试数据及相关文献,综述键合界面上金属间化合物的形成以及演变机理,并且从不同种类的金线、芯片焊盘的铝层厚度、不同焊线的模式、不同类型的封装树脂,四个方面探讨键合界面金属间化合物对可靠性的影响。

组氨酸改性MIL-53(Al)吸附重金属Pb(Ⅱ)的综合实验设计

推荐一个综合化学实验,该实验通过L-组氨酸(His-)接枝改性MIL-53(Al)得到新型MOF材料His-MIL-53(Al),研究了其对水溶液中Pb(Ⅱ)的吸附性能,并进行了Pb(Ⅱ)吸附等温线和动力学模型研究。该实验由大学生创新项目转化而来,涉及材料制备、分析表征以及表面吸附等实验手段,涵盖了配位化学、仪器分析以及物理化学等相关领域知识,适合大学高年级综合化学实验。实验的开展有助于学生了解MOF材料制备及重金属离子吸附领域的科技前沿,激发学生的科研兴趣,拓展学生的视野,培养学生的创新科研思维和综合分析能力,同时有利于增强学生的环保意识和责任意识,培养学生的团队协作精神。

Al-Mg-Si系铝合金电子束焊接头的显微组织及力学性能

采用正交试验法对厚度为4 mm的Al-Mg-Si系铝合金进行电子束焊,研究不同焊接工艺参数对接头显微组织与力学性能的影响。极差分析表明:影响接头抗拉强度的因素由大到小依次为焊接速度、电子束流、聚焦电流;方差分析表明:焊接速度和电子束流对接头抗拉强度的影响具有显著性,聚焦电流对接头抗拉强度的影响不显著。确定试验条件下的最佳工艺参数为:聚焦电流570 mA,电子束流25 mA,焊接速度16 mm/s,在该参数下获得接头的抗拉强度为212 MPa,达母材抗拉强度的65.8%。微观分析显示,接头焊缝区由柱状晶和等轴晶组成。焊缝区主要为α(Al)基体相,此外,还含有少量的Mg2Si和Al4CuMg5Si4强化相。接头区域的显微硬度测试表明:与母材区相比,熔合区的硬度有所降低。接头拉伸断口表面分布有数量较多的韧窝,呈明显的韧性断裂特征。

Analysis of the Intrinsic Uncertainties in the Laser-Driven Iron Hugoniot Experiment Based on the Measurement of Velocities

One of the most challenging tasks in the laser-driven Hugoniot experiment is how to increase the reproducibility and precision of the experimental data to meet the stringent requirement in validating equation of state models. In such cases, the contribution of intrinsic uncertainty becomes important and cannot be ignored. A detailed analysis of the intrinsic uncertainty of the aluminum-iron impedance-match experiment based on the measurement of velocities is presented. The influence of mirror-reflection approximation on the shocked pressure of Fe and intrinsic uncertainties from the equation of state uncertainty of standard material are quantified, Furthermore, the comparison of intrinsic uncertainties of four different experimental approaches is presented. It is shown that, compared with other approaches including the most widely used approach which relies on the measurements of the shock velocities of AI and Fe, the approach which relies on the measurement of the particle velocity of Al and the shock velocity of Fe has the smallest intrinsic uncertainty, which would promote such work to significantly improve the diagnostics precision in such an approach.

基于Al(OH)_(3)的熔盐法制备片状α-Al_(2)O_(3)工艺参数优化

以Al(OH)_(3)为前驱体,采用熔盐法制备片状α-Al_(2)O_(3),通过正交试验结合单因素方法研究了Al(OH)_(3)与熔盐(Na Cl+Na_(2)SO_(4))的质量比(1∶1,1∶2,1∶3)、添加剂Na_(3)PO_(4)质量分数(0.1%,1%,2%)、添加剂Ti OSO4质量分数(0.5%,1%,3%)、烧结温度(900,1050,1200℃)以及保温时间(1,3,5 h)对Al_(2)O_(3)形貌的影响,获得最优工艺参数。结果表明:由正交试验得到对片状α-Al_(2)O_(3)形貌的影响由大到小依次为烧结温度、Al(OH)_(3)与熔盐质量比、Na_(3)PO_(4)含量、保温时间,结合单因素方法得到最优工艺参数为烧结温度1050℃、Al(OH)_(3)与熔盐质量比1∶2、Na_(3)PO_(4)质量分数1%、Ti OSO4质量分数1%、保温时间3 h;在优化工艺条件下获得平均直径为15.413μm、厚度为0.765μm、径厚比为20.147的形状规则的片状α-Al_(2)O_(3),且Al_(2)O_(3)纯净、无杂质。

An Experimental Investigation into the Amalgamated Al2O3-40% TiO2 Atmospheric Plasma Spray Coating Process on EN24 Substrate and Parameter Optimization Using TLBO

Surface coating is a critical procedure in the case of maintenance engineering. Ceramic coating of the wear areas is of the best practice which substantially enhances the Mean Time between Failure (MTBF). EN24 is a commercial grade alloy which is used for various industrial applications like sleeves, nuts, bolts, shafts, etc. EN24 is having comparatively low corrosion resistance, and ceramic coating of the wear and corroding areas of such parts is a best followed practice which highly improves the frequent failures. The coating quality mainly depends on the coating thickness, surface roughness and coating hardness which finally decides the operability. This paper describes an experimental investigation to effectively optimize the Atmospheric Plasma Spray process input parameters of Al2O3-40% TiO2 coatings to get the best quality of coating on EN24 alloy steel substrate. The experiments are conducted with an Orthogonal Array (OA) design of experiments (DoE). In the current experiment, critical input parameters are considered and some of the vital output parameters are monitored accordingly and separate mathematical models are generated using regression analysis. The Analytic Hierarchy Process (AHP) method is used to generate weights for the individual objective functions and based on that, a combined objective function is made. An advanced optimization method, Teaching-Learning-Based Optimization algorithm (TLBO), is practically utilized to the combined objective function to optimize the values of input parameters to get the best output parameters. Confirmation tests are also conducted and their output results are compared with predicted values obtained through mathematical models. The dominating effects of Al2O3-40% TiO2 spray parameters on output parameters: surface roughness, coating thickness and coating hardness are discussed in detail. It is concluded that the input parameters variation directly affects the characteristics of output parameters and any number of input as well as output parameters can be easily optimized using the current approach.

合金元素对铸造Al-Si-Cu-Mg合金机械性能的影响

应用一元回归正交试验的方法研究分析了Si、Cu、Mg对Al-Si-Cu-Mg铸造合金机械性能的影响,在试验区域内建立了这三种元素含量与机械性能的关系式。考察了不同细化条件对合金性能的作用效果。同时还试验研究了两种微量元素Gd、La对合金机械性能的影响,分析了其作用机理。

SiC_p/Al复合材料切削仿真及实验研究

对SiC_p/Al复合材料的颗粒和基体分别进行定义建立有限元仿真模型,使用ABAQUS有限元软件从微观角度分析了不同切削速度和切削深度对切削力的影响以及应力场分布情况,研究切屑的形成过程、基体和颗粒的内部应力分布、刀具和颗粒之间的相互作用以及简要分析了材料表面缺陷的成因,通过车削实验进行验证。研究表明:微观仿真模型中由于高硬度SiC颗粒的存在会产生大量的微裂纹以及单一小空洞和不连续空洞,形成表面缺陷,且剪切区域微裂纹的扩展是产生切屑的重要因素;通过对比,实验获得的切削力变化及其波动和形成机制与仿真结果一致。

U_3Si_2-Al燃料板拉伸力学性能试验研究

以U3Si2-Al弥散型燃料为芯体、铝合金6061为包壳的燃料板是研究堆的新型燃料。燃料板的机械性能是燃料组件设计中的基础数据,国内外一直未对该燃料板的机械性能进行研究。本文根据国内研究堆燃料板设计的需要,对不同芯体的燃料板在不同工艺条件下的机械性能进行了测试,同时比较了不同方向的拉伸结果。为了进一步了解燃料板的机械性能,在拉伸过程中进行反复的加载试验。考虑到燃料板延伸率偏低和它的脆断状态,还用电镜检查了拉伸断口。

U_3Si_2-Al板状燃料组件冲刷试验后的解体研究

通过对U3Si2-Al板状燃料组件的解体试验研究,得到了110℃水温、7 m/s流速下50 d的水力冲刷试验和18 m/s流速下的流致振动试验对该新型燃料组件各项参数的影响,为板状燃料组件的设计、选材、加工、应用提供了实验数据。

Ti-Al-Si-O_x脱硝催化剂载体的组分优化及性能研究

采用挤出成型法制备系列Ti-Al-Si-Ox脱硝催化剂载体,评价其NH3选择性催化还原NO的活性。通过正交实验优化Ti-Al-Si-Ox配方,采用液N2-BET、ESEM及XRD分别表征载体的比表面积、孔容孔径分布、微观形貌和固相结构;采用阿基米德法测试载体的吸水率、开气孔率和体积密度。结果表明,当Ti/Al/Si摩尔比为1：0.2：0.1时,Ti Al0.2Si0.1Ox载体NH3-SCR脱除NO活性及轴向抗压碎强度匹配最好。当空速为7200 h-1,载体在450~550℃内NH3-SCR脱除NO效率均〉80%,494℃脱除NO效率达到最大值85.8%;载体抗压碎强度为6.17 MPa,比表面积为89.1 m2/g,开气孔率达63.0%,吸水率达48.3%,介孔最可几分布为8.1 nm,次可几分布为3.7 nm。Ti Al0.2Si0.1Ox脱硝催化剂载体具备优异的性能。

原位自生Al-Cr/Al复合材料制备及性能的研究

利用正交实验对Al和Cr生成的金属间化合物增强铝基复合材料进行硬度测试,探究各因素、水平对铝的增强效果,并找出最优方案。结果表明,Al-Cr/Al复合材料通过机械搅拌铸造法能成功制备;复合材料的硬度得到显著提高,最高可增强241%;其影响因素的大小依次是铬含量、铬粉粒径、搅拌温度、搅拌时间;实验的最优方案:铬含量12%,搅拌温度915℃,搅拌时间4 min,铬粉粒径48μm。

(AlBO_)w/Al复合材料制备工艺研究

为减少传统挤压铸造工艺制备金属基复合材料步骤,降低成本,用湿法制备了硼酸铝晶须预制件,并用液-固挤压法制备晶须含量为20%(体积分数)的硼酸铝晶须增强铝基复合材料((AlBO)w/Al).通过正交实验法对预制件及复合材料的制备工艺参数进行设计及筛选,并采用光学显微镜、扫描电镜等对制备的(AlBO)w/Al微观组织进行观察分析.得到预制件及复合材料制备的最佳工艺参数,发现硼酸铝晶须在基体铝合金中的分布较为均匀,与挤压铸造法相比,该方法可减少工序,降低成本.

新型Al-Cu-Li-X合金热处理强化及组织特征

采用正交试验及其方差分析、最小显著差数(LSD)法研究新型Al-Cu-Li-Ag-Mg-Zr-Ce合金的固溶和时效热处理工艺,并采用电导率、SEM、EDX、TEM等测试手段对合金热处理过程中组织结构和性能进行分析。结果表明:该合金在固溶(520℃,1.5 h,水冷)和时效(180℃,18 h,空冷)处理后,T6态显微硬度比轧制态的提高100.8%,T87态强度值达到623 MPa。固溶过程中,大量Ce、Cu、Mg、Zr溶于基体起到固溶强化作用;时效时细小片状强化相T1和薄盘状θ′相均匀弥散在基体中析出,具有强烈沉淀强化效果。

热处理工艺对锶变质近共晶Al-Si铸造合金力学性能的影响

以正交试验为基础 ,通过调整Mg含量和热处理工艺 ,分析它们对Sr变质近共晶Al Si铸造合金力学性能的影响。结果表明 ,合金强度影响因素的主次顺序为 :固溶时间、时效时间、Mg含量和时效温度 ;伸长率影响因素的主次顺序为 :Mg含量、固溶时间、时效时间和时效温度。固溶时间对抗拉强度和伸长率均为显著影响因素 ,其与固溶过程中硅相形貌发生改变有关。在合适的工艺条件下 ,合金的力学性能可达到σb≥ 315MPa ,δ≥ 6 %。

电弧喷涂Ni-Cr-Al涂层工艺优化与性能研究

采用Ni-Cr-Al丝材和PARXAIR-9935电弧喷涂系统制备镍基涂层,通过正交试验和AxioImager.A1m金相图像分析系统对Ni-Cr-Al电弧喷涂工艺进行优化;利用扫描电镜、能谱仪等方法对涂层进行分析,同时对涂层的硬度、耐磨性能进行了测试。确定优化后的工艺参数为:喷涂电流140A,喷涂电压38V,雾化空气压力0.4MPa,喷涂距离150mm。结果表明:喷涂电压、喷涂电流、雾化空气压力及喷涂距离对Ni-Cr-Al涂层孔隙率具有不同的影响,在优化的喷涂工艺参数下,Ni-Cr-Al涂层最小孔隙率可达5.20%,涂层的组织呈现出典型的层状结构特征,具有较好的硬度和耐磨损性能,可为今后电弧喷涂系统工艺参数的选定提供参考。

热喷涂工艺对Ni-Cr-Al涂层硬度性能的影响

电弧喷涂是一种热喷涂技术,该技术具有优质、高效、低成本等特点。本文运用正交试验对电弧喷涂过程中喷涂电压、喷涂电流、喷涂压力、喷涂距离对Ni-Cr-Al涂层硬度性能的影响进行了研究,分别找到了影响电弧喷涂涂层硬度的主要因素,筛选出了最佳工艺条件,为今后电弧喷涂系统工艺参数的确定提供了参考。

水下爆炸冲击下箱型隧道结构破坏试验及数值模拟

针对水下爆炸荷载作用下混凝土隧道结构的动态响应、损伤演化及其破坏问题,本文采取室内模型试验与数值计算相结合的方法,根据东湖水下隧道设计了比尺为40∶1的试件,开展了水下箱型混凝土隧道缩比模型的爆炸试验,通过监测应变信号,比较了不同乳化炸药当量下混凝土隧道试件的动态响应规律,通过测量破坏范围的大小、裂缝扩展的长度,调查了箱型隧道缩比模型试件在水下爆破荷载作用下的破坏形式;采用ANSYS/LSDYNA中S-ALE算法对试验进行了1∶1建模仿真分析,对照试验数据及破坏形态,发现模拟结果与试验结果基本一致,同时对仿真结果进一步分析得到了水下爆炸冲击波的传播完整过程和试件结构的变形规律,通过对测点应变、位移数据的统计分析,揭示了箱型隧道试件在爆炸荷载下的动态响应机理。结果表明:箱型混凝土隧道结构在横向上的应变远大于纵向上应变;隧道破坏位置主要集中在爆源附近区域以及结构转角位置,验证了S-ALE算法能够较为准确的模拟出水下爆炸下结构的动态响应及损伤演化。