Relationships between distribution characteristics of ceramic fragments and anti-penetration performance of ceramic composite bulletproof insert plates

Through quantitative statistics and morphological characterization of ceramic fragments for ceramic composite bulletproof insert plates(CCBIPs),distribution characteristics of ceramic fragments within a specific size range were analyzed for different Armor Piercing Incendiary(API)and shot times.To quantitatively evaluate the effect of energy absorption for ceramic plates,a model of energy absorption during penetration for CCBIPs was established based on statistics of the size distribution of ceramic fragments(SDCF).Variation in the SDCF and its influence on energy absorption for CCBIPs were investigated.The results indicate that the distribution feature of ceramic fragments in the range of 0.25-2.25 mm is Gaussian distribution.Compared with Type 56 of API(56-API),ceramic fragments formed by 53-API with higher kinetic energy possess more quantity and more concentrated distribution,whose average equivalence size decreases by 6.5%,corresponding to increasing by 83.9%of estimated energy absorption.Besides,the ability of CCBIPs to resist the third shot is significantly weakened,whose estimated energy absorption decreases by 58.8%compared with the first shot.More concentrated distribution and fewer fragments are formed after the third shot,the average equivalence size of ceramic fragments increases by 6.9%,which may attribute to the micro-cracks induced by the previous two shots.

Preparation and Performance of Zirconia Ceramic Ring for Slide Plate

The zirconia ceramic ring was prepared using fused monoclinic zirconia as main starting material, adopting composite stabilizer of magnesia, yttria and calcium nitrate, and applying recombination technology of traditional refractories and ceramics. Effect of the preparation process on material properties was comparatively studied, and the microstructure and phase composition were analyzed. The results show that adopting the high-speed mixing granulation process and the appropriate heat treatment can realize the control on the phase composition and microstructure, the zirconia ceramic ring with good thermal shock resitance and mechanical properties can be prepared.

Effects of gold plating on the resistance to high temperature discoloration of the cavity for ceramic packages

The effects of thickness and types of gold plating on the resistance to hightemperature discoloration of gold plating on cavity surface of ceramic package were investigated. Itwas found that the thicker gold plating, the less discoloration degree for ceramic packages.Non-cyanide gold plating performed better resistance to high-temperature aging than cyanide goldplating. The relationship between the gold plating thickness and the amount of diffused Ni to thegold plating of ceramic packages with Au/Ni and Au/Ni-Co platings after heating at 420℃ for 15 minwas also studied. When the gold plating thickness reach 2.0 μm and 1.6 μm for Au/Ni and Au/Ni-Coplating systems, respectively, no discoloration was observed on the gold plating surface of cavity,and the corresponding diffused Ni amounts (mass fraction) are 1.0% and 0.4%, while the diffused Coto the gold plating is 0.04%.

Effects of gold plating on the resistance to high temperature discoloration of the cavity for ceramic packages

The effects of thickness and types of gold plating on the resistance to high temperature discoloration of gold plating on cavity surface of ceramic package were investigated. It was found that the thicker gold plating, the less discoloration degree for ceramic packages. Non-cyanide gold plating performed better resistance to high-temperature aging than cyanide gold plating. The relationship between the gold plating thickness and the amount of diffused Ni to the gold plating of ceramic packages with Au/Ni and Au/Ni-Co platings after heating at 420℃for 15 min was also studied. When the gold plating thickness reach 2.0 μm and 1.6 μm for Au/Ni and Au/Ni-Co plating systems, respectively, no discoloration was observed on the gold plating surface of cavity, and the corresponding diffused Ni amounts (mass fraction) are 1.0% and 0.4%, while the diffused Co to the gold plating is 0.04%.

PROGRESSIVE FRAGMENT MODELING OF FAILURE WAVE IN CERAMICS UNDER PLANAR IMPACT LOADING

Polycrystalline ceramics have heterogeneous meso-structures which result in high singularity in stress distribution. Based on this, a progressive fragment model was proposed which describes the failure wave formation and propagation in shocked ceramics. The governing equation of the failure wave was characterized by inelastic bulk strain with material damage and fracture. And the inelastic bulk strain consists of dilatant strain from nucleation and expansion of microcracks and condensed strain from collapse of original pores. Numerical simulation of the free surface velocity was performed in good agreement with planar impact experiments on 92.93% aluminas at China Academy of Engineering Physics. And the longitudinal, lateral and shear stress histories upon the arrival of the failure wave were predicted, which present the diminished shear strength and lost spall strength in the failed layer.

镀铝对CoCrNiAlY-YSZ-LaMgAl_(11)O_(19)双陶瓷热障涂层高温抗氧化行为的影响

采用电弧离子镀(AIP)技术在CoCrNiAlY-YSZ-LaMA双陶瓷涂层表面沉积一层Al镀层,利用XRD、SEM和EDS等微尺度分析表征方法,全面解析涂层在大气暴露过程中的高温氧化行为。研究结果表明,未镀铝LaMA层在氧化过程中发生严重体积收缩,导致纵向微裂纹萌生和扩展。这些微裂纹成为氧气向内部扩散的通道,导致涂层呈现持续氧化增重趋势、TGO快速生长和严重的元素扩散,并最终加剧涂层断裂失效。但镀铝涂层样品表现出更好的高温抗氧化性能与结构稳定性,高温氧化过程中,表面Al镀层与氧气发生原位反应生成致密Al2O3屏障层,有效阻止或延迟氧气内部渗透,使TGO缓慢生长,其氧化增重从20h时的8.59mg/cm^(2)略微上升到80h时的9.46mg/cm^(2)。本研究结果为双陶瓷热障涂层的延寿设计与界面热生长应力调控开辟出全新技术途径和理论视野。

爆炸载荷下拼接陶瓷板膨胀破碎行为及飞散特性研究

为探究不同形状及尺寸的拼接陶瓷板在爆炸载荷下的膨胀破碎行为及飞散特性,对不同类型陶瓷平板药室的爆轰驱动过程进行了仿真,研究了陶瓷破片的粒径分布规律及陶瓷板不同位置处的破片速度和飞散角变化规律。结果表明:不同类型拼接陶瓷平板的膨胀破碎过程大致相同。拼接陶瓷片数目对陶瓷平板形成的破片数目及质量分布有较大影响,大部分破片对软目标杀伤能力小;陶瓷破片均满足Rosin-Rammler分布且拼接陶瓷片尺寸及形状影响破片的平均特征尺寸系数λ和幂指数系数k。不同类型陶瓷板水平轴向和垂直轴向破片速度变化趋势差异较大,而边缘横向及边缘纵向破片速度变化趋势相同;陶瓷平板不同位置处的破片飞散角均在-1.75~1.75°内变化,因此其杀伤区域有限。

SiC功率模块封装材料的研究进展

随着SiC功率模块的高频高速、高压大电流、高温、高散热和高可靠发展趋势,基于封装结构和封装材料的SiC功率模块封装技术也在不断地更新换代。与封装结构相比,SiC功率模块封装材料的相关研究报道较少。该文从封装材料角度出发,综述近年来陶瓷覆铜基板、散热底板、黏结材料、互连材料及灌封材料的研究进展,同时引出相关封装材料的研究重点,以满足SiC功率模块的应用需求。

三维电镀陶瓷基板激光封焊技术

气密封装是推动电子器件高可靠发展的一项重要技术,传统气密封装技术存在焊接温度高、热冲击大、应用范围窄等问题,无法满足三维电镀陶瓷基板气密封装要求。本文结合脉冲激光焊接的技术优势,研究了脉冲激光焊接三维电镀陶瓷基板实现气密封装,重点探讨了焊接过程中脉冲激光与材料相互作用模式,分析了焊接样品界面微观形貌、气密性、力学性能等。研究表明,焊接金属区裂纹的出现与基底金属铜向可伐侧的扩散密切相关;焊接过程稳定、焊接熔深小的热传导模式和过渡模式可以避免焊接裂纹出现。通过试验优化了焊接工艺参数,当激光峰值功率为120 W、脉冲宽度为1 ms、重叠率为80%时,三维陶瓷基板腔体结构获得了最佳高气密性,泄漏率为5.2×10^(-10)Pa·m^(3)/s,接头剪切强度为278.06 MPa,满足第三代半导体器件高可靠气密封装需求。

一种宽带高灵敏水声换能器的有限元分析

针对声呐系统中微型目标探测与水下定位等应用,设计了一种宽带高灵敏度水声换能器。采用双金属板压电陶瓷柱阵列材料作为换能器敏感元件,以空气代替聚合物,并在压电陶瓷柱阵列上下表面粘接金属板,改善了材料的有效机电耦合系数,提高了换能器灵敏度;通过不同厚度敏感元件嵌套式叠加,拓展了换能器工作带宽。理论分析了双金属板压电陶瓷柱阵列材料的谐振频率;利用有限元仿真确定了敏感元件的尺寸参数与材料选择,并对由该结构敏感元件组成的换能器进行了水中仿真测试。结果表明,换能器工作带宽达到约80 kHz,最大发送电压响应为188.6 dB,-3 dB带宽约为74 kHz,最大接收灵敏度为-173.9 dB。与同尺寸的纯压电陶瓷相比,该换能器的接收灵敏度和带宽都得到有效改善。

基于氮化铝HTCC的表面Cu互连制备技术

针对高集成密度、高散热封装外壳发展需求,基于氮化铝(AlN)高温共烧陶瓷(HTCC)多层基板,结合直接镀铜(DPC)工艺,提出了一种薄厚膜相结合的高散热封装基板及其制备方法。重点对氮化铝HTCC与表面铜(Cu)层间的结合力进行研究和优化,通过扫描电子显微镜(SEM)、能谱仪(EDS)和剥离强度测试仪分析和研究了界面的微观结构和力学性能。研究结果表明:与氮化铝/钛钨(TiW)/Cu相比,氮化铝/钛(Ti)/Cu界面的缺陷更少,金属Ti的黏附性能更优,拉脱断裂面在陶瓷基板上。当采用厚度为400 nm的Ti作为黏附层时,表面金属化剥离强度高达592 MPa,实现了高界面结合力,保证了产品封装性能的稳定性。

不同陶瓷颗粒表面处理对陶瓷/高铬铸铁复合材料微观界面的影响

采用传统的高铬铸铁制备电厂用磨煤机磨辊、磨盘已无法满足耐磨需求,陶瓷颗粒增强金属基耐磨复合材料成为替代传统耐磨材料的首选。本文研究了镀镍、镀钛表面处理对陶瓷/高铬铸铁复合材料微观界面的影响。结果表明,表面处理后陶瓷与高铬铸铁界面润湿性改善,可获得较好的铸渗效果。镀镍陶瓷颗粒与高铬铸铁复合材料没有明显的中间过渡层,二者之间的结合强度不高,陶瓷与高铬铸铁结合为机械结合。镀钛陶瓷颗粒与高铬铸铁复合材料的界面由于Ti元素的作用发生化学反应,形成明显的中间过渡层,界面结合强度高,陶瓷与高铬铸铁结合为冶金结合。

爆轰驱动陶瓷面背板碎裂行为研究

为研究陶瓷平板在爆轰载荷下的碎裂行为,采用AUTODYN软件对其爆轰驱动过程进行了数值计算,通过爆轰波与陶瓷平板的作用过程分析及陶瓷破片的特征尺寸统计,得到了陶瓷平板的裂纹拓展规律及陶瓷破片尺度分布规律。结果表明:不同陶瓷平板药室中爆轰波的传播及其与陶瓷平板的作用过程类似,但陶瓷裂纹拓展及形态不同,无拼接陶瓷平板形成网格化裂纹,而拼接陶瓷平板则呈现环向裂纹及径向裂纹;爆轰载荷下陶瓷平板药室形成的陶瓷破片尺度满足Rosin-Rammler分布模型;不同尺度陶瓷破片质量分布的比重由幂指数系数k决定,陶瓷平板的整体损伤程度可用平均特征尺寸系数λ评判,考虑到陶瓷平板药室的低附带损伤特性,选择小尺寸的陶瓷片进行陶瓷平板拼接较合适,研究结果可为陶瓷平板药室在轻型装甲车辆上的应用提供参考。

陶瓷平板膜在球形氧化铝提纯工序中的应用

针对四川某高新材料股份有限公司生产的高纯度球形氧化铝粉体,产品在烧球制备过程中需改变粒径的大小,烧球后的粉体具有较高的电导率和磁性,物料中还有一些杂质和金属残渣。提纯工序是产品的最后关键工序,工序采用“预处理筛分+陶瓷平板膜超滤”工艺。该工艺采用高温纯水与粉体混合成浆料,浆料与纯水混合摩擦置换出高电导率的废水,用陶瓷平板膜超滤工艺将浆料中的高电导率废水分离出来,达到提高球化率,降低电导率,去除杂质的效果。实机运行证明,陶瓷平板膜提纯处理能力为600kg/批次,每天8小时处理4个批次,120分钟/批次,过滤通量200~300L/m^(2)·h,出水稳定,浊度≤0.5 NTU,30~60天离线清洗一次;经过该工艺处理后的球形氧化铝粉体纯度≥99.9%,球化率96%~98%,pH范围7~8,电导率≤5μs/cm,其特征指标满足企业质量标准及优于GB/T24487-2022《氧化铝》标准中的化学成分和外观质量要求。

纳米陶瓷球、橡胶磁性衬板在复杂多金属矿塔磨机中的应用研究

云南都龙矿区某选矿车间处理的矿石以锌、锡为主,共伴生铜、铁、硫、铟、银等多种元素,矿物共生关系复杂,嵌布粒度粗细不均,选厂采用阶段磨矿、阶段选别工艺流程分选,一段磨矿采用半自磨+球磨SAB流程,二段磨矿采用塔磨机对中间产品进行再磨,实现了多金属矿物的高效回收。塔磨机分别采用轴承钢球和聚氨酯衬板作为磨矿介质和筒体衬板,使用过程中存在磨机运行电耗高、钢球单耗高、空载启动困难、衬板使用寿命短及拆装困难等问题。开展纳米陶瓷球、橡胶磁性衬板在锌粗精矿塔磨中的应用研究后,锌粗精矿再磨粒度-37μm含量达到75%以上,推广应用到锡石次精矿和锡石中矿塔磨再磨系统-74μm含量达到70%以上,磨矿效果得到了明显改善,同时磨机电耗、介质单耗显著降低,橡胶磁性衬板使用寿命是聚氨酯衬板的5倍以上,经济效益可观。

陶瓷薄板-铝蜂窝复合幕墙面板温度变形有限元分析

陶瓷薄板和铝蜂窝板的热膨胀系数相差较大,在温度变化较大时将会产生较大的变形。以郑州市幕墙装饰工程为研究背景,基于ANSYS模拟软件进行简便有效的有限元分析,通过参数化建立模型,分析在温度荷载作用下,铝蜂窝芯尺寸和蜂窝蒙皮板对复合板变形量的影响,为减小温度变形提供技术控制措施,对于将陶瓷薄板-铝蜂窝复合板广泛应用于幕墙面板装饰有一定的借鉴与参考作用。

平板型太阳能集热板研究进展

传统平板太阳能集热器因生产工艺简单、制造成本低、安装维修方便以及能够与建筑耦合集成等特点,在国内外得到广泛应用。太阳能集热板是太阳能集热器的关键部件,近二十年来,研究者不断创新太阳能集热板的制造工艺,以期获得革命性突破,实现节约和替代常规能源的目的。研究从生产工艺、集热性能、使用寿命和市场用途等方面分析了平板型太阳能集热板的发展现状,剖析了平板型太阳能集热板的优缺点,并展望了平板型太阳能集热板的市场前景。瓷铝复合集热板改变了板芯生产方法和涂层制备工艺,在成本、寿命和效率等方面优势明显,光伏/光热一体板将光伏技术与光热技术相结合,可同时满足居民用电和用热需求,在用途方面更具发展潜力。

平板陶瓷膜MBR工艺在农村污水处理中的应用

随着我国农村污水处理需求的日益增长,平板陶瓷膜MBR工艺作为一种高效、稳定的污水处理技术被广泛应用。该工艺具有高效、稳定的优势,不仅可以提高农村污水的处理效率,还能够降低运维成本、保护环境,并实现污水资源的再利用,因而在农村污水处理领域有着广阔的应用前景。本文通过综合分析平板陶瓷膜MBR工艺在农村污水处理领域的应用情况,探讨了其在提高农村污水处理效率、降低运维成本、保护环境等方面的优势。

氧化石墨烯/陶瓷球增强聚氨酯SPS复合板抗侵彻性能

无机填料的加入,能够较大程度增强聚氨酯的性能,从而使以聚氨酯为芯层的复合结构性能得到提升。为得到具有更好抗侵彻能力的SPS(sandwich plate system)复合板,利用原位聚合法得到氧化石墨烯增强聚氨酯弹性体并对其进行单轴拉压测试,在此基础上加入陶瓷球作为新的增强相,以Q235钢作为面板制备了芯层为石墨烯增强聚氨酯以及石墨烯/陶瓷球增强聚氨酯的SPS复合结构,通过钢球弹的侵彻试验并运用LS-DYNA数值仿真得到两种复合板的弹道极限速度,分析其吸能特性及损伤机理。结果表明:当石墨烯质量分数w=0.4%时,石墨烯增强聚氨酯的压缩模量较纯聚氨酯提高了32.4%,拉伸强度提高了42.6%;在加入陶瓷球后,复合板的弹道极限速度提高了20.8%,陶瓷球的碎裂和偏移中断了径向应力的传播,子弹尺寸以外的陶瓷球较为完整。