High Heat Flux Testing of B_4C/Cu and SiC/Cu Functionally Graded Materials Simulated by Laser and Electron Beam

B4C, SiC and C, Cu functionally graded-materials (FGMs) have been developed by plasma spraying and hot pressing. Their high-heat flux properties have been investigated by high energy laser and electron beam for the simulation of plasma disruption process of the future fusion reactors, And a study on eroded products of B4C/Cu FGM under transient thermal load of electron beam was performed. In the experiment, SEM and EDS analysis indicated that B4C and SiC were decomposed, carbon was preferentially evaporated under high thermal load, and a part of Si and Cu were melted, in addition, the splash of melted metal and the particle emission of brittle destruction were also found. Different erosive behaviors of carbon-based materials (CBMs) caused by laser and electron beam were also discussed.

Preparation and Arc Breakdown Behavior of Nanocrystalline W-Cu Electrical Contact Materials

Nanostructured （NS） W-Cu composite powder was prepared by mechanical alloying （MA）, and nanostructured bulk of W-Cu contact material was fabricated by hot pressed sintering in an electrical vacuum furnace. The microstructure, electric conductivity, hardness, breakdown voltage and arcing time of NS W-Cu alloys were measured and compared to conventional W-Cu alloys prepared by powder metallurgy. The results show that microstructural refinement and uniformity can improve the breakdown behavior, the electric arc stability and the arc extinction ability of nanostructured W-Cu contacts materials. Also, the nanostructured W-Cu contact material shows the characteristic of spreading electric arcs, which is of benefit to electric arc erosion.

Fabrication of W/Cu and Mo/Cu FGM as Plasma-facing Materials

W/Cu Functionally Graded Materials (FGM) was designed not only for reducing the thermal stress caused by the mismatch of thermal expansion coefficients, but also for combining the features of W, Mo - high plasma-erosion resistance and the advantages of Cu - high heat conductivity and ductility. Four different fabrication processes for W/Cu or Mo/Cu, including hot-pressing, Cu infiltration of sintered porosity-graded W skeleton, spark plasma sintering and plasma spraying, were investigated and compared. It was foundthat the hot-pressing process is difficult to keep the designed composition gradient, while the other three processes are successful in making W/Cu or Mo/Cu FGM. Meanwhile, microstructures and composition gradients are analyzed with SEM and EDAX.

Arc erosion behavior of a nanocomposite W-Cu electrical contact material

The erosion behavior of a nanocomposite W-Cu material under arc breakdown was investigated. The arc erosion rates of the material were determined, and the eroded surfaces and arc erosion mechanisms were studied by scanning eleclion microscopy. It is concluded that the nanocomposite W-Cu electrical contact material shows a characteristic of spreading arcs. The arc breakdown of a commercially used W-Cu alloy was limited in a few areas, and its average arc erosion rate is twice as large as that of the former. Furthermore, it is also proved that the arc extinction ability and arc stability of the nanocomposite W-Cu material are excellent, and melting is the major failure modality in the make-and-break operation of arcs.

Electrical Breakdown Characteristic of Nanostructured W-Cu Contacts Materials

Nanostructured （ NS ）W-Cu composite powder was prepared by mechanical alloying （ MA ）, and nanostructared bulk of W-Cu contact material was fabricated by hot press sintering in an electrical vacuum furnace. The rnicrostructure, electric conductivity, hardness and break down voltage of NS W- Cu alloys were measured and compared to those of conventional W-Cu alloys prepared by powder metallurg＇y. The experimental results show that microstructural refinement and uniformity can improve the breakdown behavior and the electric arc stability of nanostructared W- Cu contacts materials. Also, the wanostructured W- Cu contact material shows the characteristic of spreading electric arcs, which is of benefit to electric arc erosion.

三维互穿结构Cu-W触头抗熔焊机理

触头闭合回跳电弧引起的开关电器动熔焊问题,直接影响大功率接触器的电寿命和可靠性。为此设计了2种三维互穿有序结构的四边形和菱形十二面体的Cu-W复合材料触头,围绕触头动熔焊过程中的电弧、熔池、液滴溅射及凝固相变降温等问题,建立触头熔池流体动力学模型和冷凝降温数学模型,研究了2种有序结构和商用无序结构的触头阳极在闭合回跳电弧作用下熔化温度分布、熔池喷溅形貌和接触区域金属凝固过程,通过模拟熔焊实验平台进行了熔焊力验证。结果表明,通过调节三维互穿有序W骨架结构,能够有效抑制熔池扩散和液态金属喷溅,并降低熔焊力,从而提高Cu-W复合材料的抗熔焊性能。

熔渗-焊接法制备W/Cu功能梯度材料的研究

采用熔渗－焊接法经过梯度W骨架制备，渗Cu及热压焊接三个步骤制备出W／Cu功能梯度材料。并对W／Cu梯度过渡层的显微结构进行了观察．

热压法制备W/Cu功能梯度材料

对热压法制备W/Cu功能梯度材料的可行性进行了研究 ,并对其组织结构进行了观察 ,对其表观抗弯强度及抗热震性进行了测试 .结果表明在 1 80 0℃ ,1 8N/mm2 ,2h条件下可以制备Cu含量最高为 2 2 .5 5vol.%的W/Cu功能梯度材料 ,其密度可达理论密度的 94.6% .热压W/Cu功能梯度材料的成分分布与最初设计的成分分布有较大偏差 .

W/Cu功能梯度材料的制备及热循环应力分析

采用水煮溶解造孔剂法,即先制备孔隙呈梯度分布的钨骨架、后渗铜的方法,制备了W/Cu功能梯度材料,并对钨铜在纵截面的分布进行了检测,数据表明在纵截面上钨铜呈梯度分布。利用水淬法模拟其服役状况并用有限差分方法对产生的非稳态热应力进行了分析。结果表明,热应力的最大值总是出现在两端,由于富钨端相对密度较低,裂纹总是在该端出现,模拟结果与实验结果相一致。

WCu梯度功能材料的高热负荷性能研究

用等离子体喷涂和热压方法制作了W Cu梯度功能材料(FGM)样品,用大功率ND∶YAG激光对其进行了高热负载模拟实验。结果表明,在100～400MW·m-2的瞬时(脉冲宽度为4ms)热负载下,经过200～700次热循环,未发现有W Cu复合体开裂。在123MW·m-2的功率密度下作用700次,发现钨表面有再结晶现象及严重的晶界腐蚀和裂纹,再结晶的平均晶粒尺寸约为5～10μm,垂直于表面呈柱状结构,再结晶层厚度约20～30μm。由于激光的淬冷效应,晶粒生长的趋势并不明显。在398MW·m-2功率密度下出现了明显的腐蚀坑,坑内呈疏松的蜂窝结构,坑的边缘出现了明显沉积区,能谱分析表明沉积区集聚了大量的金属杂质。等离子体喷涂试样比热压试样更易产生晶界的断裂的裂纹。在相同的热负荷条件下,W CuFGM的重量损失低于石墨材料的重量损失。

W/Cu梯度功能材料板稳态热应力分析

采用解析法研究了W/Cu梯度功能材料板的残余热应力和在稳态梯度温度场下的工作热应力的大小和分布状况。结果表明:随着成分分布指数的增加,残余热应力与工作热应力的最大值先减小后增大,当成分分布指数(P)取1时,达到最小值;随着梯度层数的增加,热工作热应力的最大值逐渐减小,但当梯度层数达到6时,随着梯度层数的增加,缓和效果并不明显;当梯度层厚度增加到5 mm时,工作热应力的最大值约为非梯度材料工作热应力最大值的50%。

添加Y_2O_3对CuW触头材料性能的影响

采用熔渗法制备添加Y_2O_3的CuW合金,研究了添加Y_2O_3对CuW材料静态性能、真空电击穿性能及显微组织的影响.结果表明:Y_2O_3的添加量为0～0.4%(质量分数)时,随着添加量的增加,合金的硬度逐渐升高,而电导率变化不大;当添加量为0.4%～1.2%时,硬度和电导率则明显下降.添加Y_2O_3相提高了CuW合金的耐电压强度,降低了材料的截流值添加Y_2O_3的CuW合金阴极斑点较小,锕液的飞溅现象减少.

溶胶-喷雾干燥W-10Cu和W-20Cu复合粉末烧结与组织性能研究

采用超细复合粉末直接烧结和传统W骨架熔渗两种方法制备W-10Cu、W-20Cu合金。研究两种方法制备的合金的致密化、显微组织与导电性能,并重点研究了超细复合粉末短时间内烧结和在高温烧结时的致密化行为。结果表明,超细W-10Cu、W-20Cu复合粉末在1200～1420℃烧结,相对密度均达到了99.1%,致密化与合金中的晶粒度和W-Cu复合粉末中的Cu相成分密切相关。与传统熔渗方法相比,超细复合粉末制备的合金显微组织细小、均匀,而且两者导电性能接近。

第一壁材料W/Cu界面设计与制备研究现状

介绍了目前解决W/Cu连接界面缓解热应力的方法——添加适配层。在对不同适配层进行分析后,选出最佳W/Cu适配层,再对W/Cu适配层进行结构优化分析,得出选用W/Cu功能梯度材料作为适配层具有足够的结合强度,而且良好的导热性能能有效地缓解热应力。此外,重点阐述了目前成功的制备的W/Cu功能梯度材料用作W/Cu第一壁材料的适配层的常用方法。最后,对W/Cu功能梯度材料用作适配层解决W/Cu第一壁材料连接界面的问题做出了总结和展望。

机械合金化制备的纳米晶W-Cu电触头材料

采用真空高温热压熔渗烧结工艺制备出密度为 99 5 %的纳米晶W Cu电触头材料。其组织结构和晶粒大小采用SEM ,TEM和XRD观察。同时就纳米晶W Cu电触头材料的硬度、电导率、耐电压强度和抗电弧烧蚀性与传统粉末冶金工艺制备的进行了对比分析。结果表明 ,纳米晶W Cu电触头材料的硬度、抗电弧烧蚀性及耐电压稳定性远优于传统熔渗法的W Cu合金 ,而电导率两者相差不大。

不同稀土元素对W-Cu电触头材料性能的影响

利用粉末冶金熔渗技术制备出添加不同稀土的W-Cu-RE电触头材料。比较不同稀土对其组织和力学性能的影响,并通过扫描电镜分析电弧烧蚀后的微观组织形貌。结果表明,W-Cu合金中最适宜添加的稀土单质为La,它使粘结相Cu呈连续网络分布。W-Cu-RE电触头材料较传统的W-Cu合金抗电弧烧蚀性能有了明显提高,达到30%。主要原因是触头间产生的电弧由于稀土的加入更容易使金属Cu气化而带走大量热能,从而起到保护基体的作用。

W-Cu触头材料的微波烧结

采用微波烧结技术制备W-25Cu触头材料,并与常规烧结进行对比。结果表明:微波烧结升温速度快,周期短,能促进W-Cu材料的致密化;在适当条件下,微波烧结能获得相对密度达99.8%的W-Cu样品;微波烧结能改善W-Cu样品中两相分布的均匀性和W晶粒尺寸的一致性,但引起W晶粒的快速长大;Fe烧结助剂导致W-Cu材料显微组织均匀性变差,并引起晶粒进一步粗化;微波烧结技术能够应用于W-Cu材料的制备,在缩短生产周期、降低生产成本方面具有潜在优势。

W-Cu梯度功能材料的热物理性能

对采用不同粒度配比和热压制备的W-Cu梯度功能材料的热物理性能进行研究。结果表明:梯度材料的整体热导率较高,达到226.4W/(m.K),高于过渡层W/Cu33的热导率,低于散热层W/Cu50的热导率;封接层具有低的线性热膨胀系数,αRT～100℃=6.82×10-6/℃满足与BeO基板材料封接匹配的要求;低温热条件下制备的W-Cu梯度功能材料各梯度层的热膨胀系数具有良好的可控性和可设计性能,其实测值与理论值十分接近,其误差值低于6%;耐热冲击温度达到800℃以上,热疲劳性能可达500℃水淬50次以上。

W-Cu面对等离子体梯度热沉材料的制备和性能

采用粉末冶金法制备了W-Cu面对等离子体梯度热沉材料。对其显微组织、界面以及重要的热学、力学性能进行了研究。显微组织观察表明:截面成分呈梯度分布,并通过高温下元素的扩散,实现了组织的连续变化,层间没有明显界面;烧结后Cu形成了连续的网络结构,分布在W颗粒周围。W-Cu梯度材料的化学元素分布和热学、力学性能沿厚度方向呈梯度变化,材料整体的热导率达151.4 W.(m.K)-1。在800℃温差条件下,对材料分别进行抗热震和耐热疲劳实验。热震实验后,界面处未发现裂纹和开裂现象,表现出良好的抗热震性能。经过83次热循环冲击后,观察到了裂缝,并探讨了裂缝形成机制。

W/Cu和W/C涂层的循环热负荷实验

用等离子体喷涂和热压方法制作了W /Cu梯度功能材料和W /C涂层 ,其中W/C涂层具有多层的钨 (W )、铼 (Re)扩散阻挡势垒。为了试验这些复合材料能否经受聚变等离子体破裂时的高热负荷 ,用大功率ND :YAG激光进行了模拟实验。结果表明 :在 1 0 0～ 4 0 0MW /m2 的瞬时 (脉冲宽度为 4ms)热负荷作用下 ,经过 2 0 0～ 70 0次热循环 ,未发现W /Cu复合体的开裂。其中在 1 2 3MW /m2 的功率密度下作用70 0次后 ,发现等离子体喷涂试样表面的再结晶现象和严重的晶界腐蚀 ,由于激光的冷效应 ,晶粒生长的趋势并不明显 ,再结晶层的晶粒呈垂直于表面的柱状结构。W/C试样的退火实验表明 ,钨涂层的再结晶温度稍高于 1 4 0 0℃。在更高的功率密度下 (3 98MW /m2 )出现了明显的腐蚀坑 ,坑内呈疏松的蜂窝结构 ,坑的边缘形成了沉积区 ,能谱分析表明沉积区集聚了大量的金属杂质。等离子体喷涂试样比热压试样更易产生晶界的断裂和裂纹。在同等的热负荷条件下 ,W