Resistance of cavitation erosion of multimodal WC-12Co coatings sprayed by HVOF

Conventional,submicron and multimodal WC-12Co cermet coatings were deposited by high velocity oxy-fuel（HVOF）.The microhardness and microstructure of the coatings were compared,and the resistance of the coatings to cavitation erosion was studied by ultrasonic vibration cavitation equipment.Cavitation pits and craters were observed by SEM and cavitation mechanisms were explored.The results show that the microstructures of submicron and multimodal WC-12Co coatings prepared by HVOF are dense with little porosity,and their microhardness values are obviously higher than that of the conventional WC-12Co coating.The average microhardness of multimodal WC-12Co coating reaches nearly HV1500,which is much higher than that of the conventional one.As well,it is found that the multimodal WC-12Co coating exhibits the best cavitation erosion resistance among the three coatings,the erosion rate is approximately 40% that of the conventional coating,and the cavitation erosion resistance of multimodal WC-12Co coating is enhanced by above 150% in comparison with the conventional coating.

激光粉末床熔融WC-12Co硬质合金温度场模拟

结合有限元软件ANSYS建立三维有限元热模型,利用APDL命令及生死单元方法实现对高斯热源的施加和WC-12Co硬质合金打印过程的模拟,得到WC-12Co硬质合金在激光粉末床熔融(LPBF)成形过程中的温度场分布,研究不同工艺参数(激光功率、扫描速度)对温度场分布及熔池特征的影响。结果表明:WC-12Co硬质合金在LPBF过程成形时,利用有限元能够有效模拟其成形过程。位于热源前部的等温线比尾部更为密集,温度梯度更大;而扫描路径终端边缘处熔池中心的温度最高。随着激光功率的增大和扫描速度的减小,熔池宽度、深度和长度均相应增大。通过相关实验分析不同工艺参数对晶粒尺寸的影响,发现晶粒尺寸随扫描速度的增加而减小,随激光功率的增加而增大;但过高的激光功率会引起一定的热裂纹现象发生。

M2高速钢表面激光熔覆WC-12Co梯度涂层的制备工艺与实验研究

文章采用COMSOL数值模拟软件,对M2高速钢表面熔覆WC-12Co涂层和添加Ni60过渡层熔覆WC-12Co梯度涂层进行数值模拟与分析。探究温度梯度随时间的变化规律,并结合梯度实验及涂层的宏观形貌与微观组织分析,总结梯度熔覆的热量耦合控制方法。模拟及实验结果表明:添加Ni60过渡层制备WC-12Co梯度涂层的温度梯度远远小于直接熔覆制备WC-12Co涂层的温度梯度;添加Ni60过渡层制备WC-12Co涂层可以利用直接熔覆制备WC-12Co涂层的激光功率,也可以扩大熔覆制备WC-12Co涂层的功率区间,有利于提高熔覆制备效率;添加Ni60过渡层能够改善涂层内部缺陷,细化组织晶粒;Ni60过渡层中的Ni元素扩散导致WC-12Co涂层的硬度降低,但仍高于基体的硬度性能。

基于灰色关联分析法的电火花沉积WC-12Co涂层工艺参数优化

以WC-12Co为电极,氩气作为保护气体,在FS438钢表面电火花沉积WC-12Co涂层。选择电压、电容、频率和沉积时间为加工参数,采用正交实验方法进行实验,并对实验结果进行极差分析。对正交实验结果的涂层厚度和表面粗糙度进行无量纲化,计算其关联系数、关联度值,并进行灰色关联分析,最终实现多指标工艺参数的优化。利用光学显微镜,分析工艺参数优化后沉积层的表面形貌。结果表明:对WC-12Co涂层厚度和表面粗糙度影响最大的加工参数为电压和电容。当工艺参数为电压50 V、电容120μF、频率360 Hz、沉积时间4 min/cm^(2)时,所制备的WC-12Co涂层厚度为55.125μm,表面粗糙度为5.073μm,涂层表面较致密,光洁度较好,该涂层的厚度与表面粗糙度指标综合性能较为良好。

碳含量对超细晶WC-12%Co硬质合金组织及性能的影响

经混料、压形、热等静压烧结制备了8组不同碳含量的WC-12%Co硬质合金,采用金相显微镜、扫描电镜、硬度计、电子万能力学试验机分析了碳含量对合金微观组织及力学性能的影响。结果表明:碳含量为5.26%~5.42%的WC-12%Co硬质合金处于WC+γ二相区;当碳含量小于等于5.22%时,合金出现絮状、针状脱碳相;当碳含量大于等于5.46%时,合金出现黑色絮状的渗碳相,伴有粗晶、粗晶聚集及钴偏析现象。随着碳含量逐渐增加,WC晶粒逐渐长大,结晶趋于完整,晶粒边缘趋于平直化,晶界变得更加清晰,当碳含量达到5.54%时,WC晶粒边缘出现圆角。碳含量为5.26%~5.42%的合金处于WC、Co二相区,综合力学性能较优,硬度维持在1 777~1 695 kg/mm^(2),抗弯强度为3 357~3 290 MPa。

Microstructure and properties of WC-12Co composite coatings prepared by laser cladding

A comprehensive study of the phase composition, microstructure evolution, microhardness and wear performance of WC-12 Co composite coatings fabricated by laser cladding using coaxial powder-feed mode was presented. It was shown that a combination of high scan speed and high laser energy density made WC on the edge of WC-12 Co composite powders partially melt in liquid Co and 304 stainless steel matrix, and then new carbides consisting of lamellar WC and herringbone M3 W3 C(M=Fe,Co) were formed. Meanwhile, WC-12 Co composite coatings with no porosity, cracks and drawbacks like decarburization were obtained, showing high densification and good metallurgical bonding with the substrate. Furthermore, a considerably high microhardness of HV0.3 1500-1600, low coefficient of friction of 0.55 and wear rate of(2.15±0.31)×10-7 mm3/(N·m) were achieved owing to the synergistic effect of excellent metallurgical bonding and fine microstructures of composite coating under laser power of 1500 W.

复合添加Cr_(3)C_(2)/VC/TaC的WC-12%Co超细晶硬质合金的组织和性能研究

研究了复合添加不同含量的Cr_(3)C_(2)、VC、TaC三种晶粒长大抑制剂对WC-12%Co超细晶硬质合金组织及性能的影响。结果表明,与采用Cr_(3)C_(2)+VC组合晶粒长大抑制剂的合金相比,采用Cr_(3)C_(2)+VC+TaC组合晶粒长大抑制剂的合金的综合力学性能呈降低趋势,但导热性能更好。采用Cr_(3)C_(2)+VC+TaC组合晶粒长大抑制剂的合金的组织和力学性能取决于晶粒长大抑制剂的抑制效果,而不是其添加总量,优化三种抑制剂的配比是提升合金性能的关键。

低碳WC-12Co涂层制备工艺参数优化及熔锌腐蚀性能研究

为优化镀锌沉没辊表面涂层的抗熔锌腐蚀性能,采用超音速火焰喷涂技术在316L不锈钢基体上制备了低碳WC-12Co涂层,并设计了4因素3水平[L9(3^(4))]正交试验对喷涂工艺进行了优化,分别对低碳WC-12Co涂层的相结构、显微组织、孔隙率、结合强度和抗熔锌腐蚀性能进行了测试。结果表明:喷涂工艺参数的变化对涂层的相结构的影响很小,但对涂层的孔隙率影响显著,喷涂工艺参数中各因素对涂层孔隙率的影响按从大到小排列顺序为:煤油流量>喷涂距离>送粉率>氧气流量。获得最低孔隙率WC-12Co涂层喷涂工艺参数如下:煤油流量为26.5 L/h,氧气流量为55.2 m^(3)/h,送粉率为60 g/min,喷涂距离为326 mm,在这一参数下制备的高致密度的低碳WC-12Co涂层对熔融的锌液能起到很好的隔离作用,适合用于镀锌沉没辊的表面防护。

Wear resistance of Zr/WC composite coatings on Cr12MoV steel surface by electric spark deposition

Zr/WC composite coating was prepared on the surface of Cr12MoV steel by electric spark deposition technology to change its surface properties. The surface and worn surface morphology of the coating were observed using scanning electron microscope. Dry friction and wear tests of the coatings were carried out at room temperature. The results show that the coating is continuous and uniform, and the thickness was about 50-60 μm. The microhardness of the coating surface was highest at 1140 HV_(200g), which was significantly higher than that of the substrate. The ear tests results show that the wear weight loss, wear volume and wear rate follow the following rules: Cr12MoV>WC coating> Zr/WC composite coating.

Effects of Yttrium Ion on Formation Mechanism of ZrO_2-Y_2O_3 Ceramic Coatings Formed by Plasma Electrolytic Oxidation on Al-12Si Alloy

ZrO2-Y2O3 ceramic coating was produced by plasma electrolytic oxidation （PEO） on ZAlSil2Cu3Ni2 alloy. The microstructure and phase composition of the coating were investigated by SEM and XRD.： The results show that adding an appropriate amount of yttrium ion can improve the growing rate of ceramic coating at different oxidation stages and decrease arc voltage. The thickness of ZrO2-Y2O3 coating is 16 μn thicker than that of ZrO2 coating and the maximum oxidation rate improves by 0.6 μm/min. In addition, the arc voltage decreases from 227 to 172 V. It can be seen that the rate of oxidation firstly increases to some extent and then decreases with the content of yttrium ion increasing. The growth rate reaches the maximum while the content of yttrium ion is 0.05 g-L-1The maximum thickness is 90 μm.Compared to ZrO2 coating, the micropores of ZrO2-Y2O3 coating are less and the ceramic layer is repeatedly deposited by ZrO2 and Y2O3 ceramic particles. Meanwhile, the binding force between coating and substrate is better and the coating is uniform and compact. The ceramic layer is mainly composed of c-Y0.15Zr0.85O1.93□0.07, m-ZrO2, α-Al2O3, ,γ-Al2O3 and Y2O3. It is indicated that ZrO2 has beert fully stabilized by yttrium ion through the formation of solid solution.

大气等离子喷涂Y_(3)Al_(5)O_(12)/Al_(2)O_(3)陶瓷涂层的CMAS腐蚀抗力

探索能够有效抵抗1300℃及以上温度钙镁铝硅酸盐(Calcium-Magnesium-Aluminum-Silicate,CMAS)腐蚀的新材料是近年来先进航空发动机用环境障涂层研究的重点任务。本工作围绕具有超强CMAS腐蚀抗力的YAG(Y_(3)Al_(5)O_(12))/Al_(2)O_(3)体系,采用大气等离子喷涂(Atmospheric Plasma Spraying,APS)技术制备了具有共晶成分的YAG/Al_(2)O_(3)涂层。通过在1100、1300和1500℃对制备态涂层进行热处理,获得了具有不同微观结构的YAG/Al_(2)O_(3)涂层。利用不同表征手段研究了YAG/Al_(2)O_(3)涂层抵抗1300℃CMAS腐蚀的性能及微观结构对涂层腐蚀抗性的影响。研究结果发现,经不同温度热处理的YAG/Al_(2)O_(3)涂层与CMAS的反应产物均为石榴石结构固溶体、CaAl_(2)Si_(2)O_(8)和Ca_(2)MgSi_(2)O_(7)。腐蚀机制研究发现,1100℃热处理YAG/Al_(2)O_(3)涂层与CMAS反应界面的近连续分布石榴石固溶体层可有效阻隔CMAS腐蚀元素的扩散;1500℃热处理YAG/Al_(2)O_(3)涂层晶粒尺寸的增加及晶界数量的减少可降低涂层材料在CMAS中的溶解速率,二者均可通过影响腐蚀过程中的离子传输速率而影响各生成物的竞争析出,进而提升涂层的CMAS腐蚀抗力。本工作为YAG/Al_(2)O_(3)涂层热处理工艺优化提供了借鉴,并为通过微观结构优化调控YAG/Al_(2)O_(3)涂层的CMAS腐蚀抗力提供了新思路。

低成本Nb掺杂Li_(7)La_(3)Zr_(2)O_(12)固态电解质的性能与应用研究

固态电池因其在能量密度、循环寿命和安全性等方面的优异性能受到关注。其核心组件为固态电解质材料。具有石榴石结构的Li_(7)La_(3)Zr_(2)O_(12)(LLZO)氧化物固态电解质由于具备宽电化学窗口、良好的离子传导性、稳定的化学性能及简单的制备工艺等特点而得到广泛研究。本研究采用Nb元素对LLZO进行掺杂,成功制备得到Li_(6.75)La_(3)Zr_(1.75)Nb_(0.25)O_(12)(LLZNO)氧化物固态电解质,其离子电导率达到了7.79×10^(-4)S/cm,且制备成本与未掺杂的LLZO相比无明显增加。将其涂覆在聚乙烯(PP)隔膜表面形成PP-LLZNO隔膜,表现出良好的热稳定性和离子电导率。与Al_(2)O_(3)涂覆隔膜或固态电解质Li_(6.75)La_(3)Zr_(1.75)Ta_(0.25)O_(12)(LLZTO)涂覆隔膜组装的电池相比,组装了PP-LLZNO涂覆隔膜的扣式电池和软包电池的容量保持率分别达到了84.99%(50圈)和57.40%(100圈),展现出更优异的性能。因此,高离子电导率和低成本LLZNO的制备对固态电解质的大规模生产及在固态电池中的广泛应用具有一定的参考意义。

Adhesive strength and structure of micro-arc oxidation ceramic coatings grown in-situ on LY12 aluminum alloy

The ceramic coatings containing zirconium dioxide were grown in-situ on LY12 aluminium alloy by micro-arc oxidation in mixed zirconate and phosphate solution. The phase composition and morphology of the coatings were studied by XRD and SEM. The adhesive strength of ceramic coatings was assessed by thermal shock test and tensile test. The results show that the coating is composed of m-ZrO2,t-ZrO2, and a littleγ-Al2O3. Along the section of the coating, t-ZrO2 is more on both sides than that in the middle, while m-ZrO2 is more in the middle than that on both sides. Meantime the coating is also composed of a dense layer and a loose layer. The coating has excellent thermal shock resistance under 550℃and 600℃. And tensile tests show the adhesive strength of the dense layer of the coating with the substrate is more than 17.5 MPa.

Al_(0.25)Li_(6.25)La_(3)Zr_(2)O_(12)包覆LiCoO_(2)降低锂离子电池界面阻抗

本论文通过固相烧结法制备Al_(0.25)Li_(6.25)La_(3)Zr_(2)O_(12)(LLZO)包覆的LiCoO2(LCO)材料,以提高其界面稳定性并降低界面阻抗为目的。实验结果表明,电化学性能明显得到改善。在3.0-4.62 V的电压区间充放电50圈,包覆后材料的比容量保持率为70%,高于未包覆的65%。此外,包覆后材料的电荷转移电阻从22.5Ω降低至15.0Ω,倍率性能得到较大改善。本工作研究了固态电解质LLZO包覆钴酸锂对电性能的影响,对快充钴酸锂电池材料的设计具有较大参考意义。

等离子喷涂纳米WC-12％Co涂层与陶瓷和不锈钢配副时的摩擦磨损性能对比研究

利用大气等离子喷涂技术制备了纳米和微米WC-12% Co涂层,采用SRV摩擦磨损试验机考察了纳米和微米WC-12%Co涂层在干摩擦条件下分别与Si3N4陶瓷球和不锈钢球配副时的摩擦磨损性能.结果表明:在相同试验条件下,纳米和微米WC-12% Co涂层分别与Si3N4陶瓷球和不锈钢球配副时的摩擦系数相差不大,但纳米WC-12% Co涂层的抗磨性能明显优于微米WC-12% Co涂层;2种涂层的磨损机制差异亦较小,纳米涂层在低载荷下的主要磨损机制为微断裂和轻微磨粒磨损,而在较高载荷下的磨损机制为硬质相的剥落和磨粒磨损;微米涂层在较低载荷下的磨损机制为微断裂和磨粒磨损,在较高载荷下为疲劳磨损.在相同试验条件下,纳米WC-12% Co涂层的磨损表面损伤明显较轻微.

爆炸喷涂WC-12%Co涂层的滑动磨损性能

采用爆炸喷涂技术制备纳米和普通WC-12%Co涂层,用往复试验机对涂层的干滑动磨损性能进行了研究,分析了涂层磨损前后的形貌、结构及成分变化。结果表明:相同的喷涂条件下,WC-12%Co纳米涂层比普通涂层结构均匀、致密,但碳化物分解严重。尽管纳米涂层与普通涂层具有相近的硬度,但普通涂层的耐磨性优于纳米涂层,尤其是在重载条件下。普通涂层的磨损机制为微切削;纳米涂层在轻载(10 N)下,以塑性变形为主要磨损机制,随载荷增加至30 N,纳米WC粒子不能起到阻抗陶瓷球对磨副的磨削作用,而是随粘结相一起被去除,同时由于纳米涂层脱碳导致的层间结合薄弱,在滑动磨损中易发生成片剥落,耐磨性大幅下降。

HVOF喷涂纳米结构WC-12Co涂层的组织结构分析

纳米结构WC-12Co涂层的研究目前已受到了广泛重视,对其组织结构及影响因素的研究有利于提高涂层性能。采用HVOF工艺制备了纳米结构、多峰结构及普通微米结构3种WC-12Co金属陶瓷复合涂层,并采用SEM、XRD等对粉末及涂层的显微形貌、组织结构进行了分析;探讨了粉末在喷涂过程中的氧化脱碳机理,并指出了与之相关的影响因素。结果表明:纳米结构WC-12Co涂层结构致密,孔隙率低,与基体结合状态良好;纳米粉末在喷涂过程中比微米粉末氧化失碳严重,并发生了不同的纳米晶粒的长大;纳米粉末在喷涂过程中的氧化脱碳程度不仅与喷涂工艺有关,还在很大程度上取决于粉末本身的结构特性。

HVOF制备亚微米结构WC-12Co涂层性能研究

采用超音速火焰(HVOF)喷涂工艺制备了亚微米结构WC-12Co涂层,测试了这种亚微米涂层的结合强度、显微硬度及抗磨粒磨损性能,并利用XRD对喷涂粉末及涂层进行相结构分析,用扫描电子显微镜对喷涂粉末、磨粒磨损前后的涂层表面形貌进行观察.研究结果表明:喷涂过程中,亚微米结构WC粒子没有明显的脱碳分解发生,涂层组织结构致密,其显微硬度平均值高达HV1105;在相同的试验条件下,16Mn钢的磨粒磨损量是亚微米WC-12Co涂层的7.8倍,这表明亚微米结构涂层具有优异的抗磨粒磨损性能.

HVAF制备WC-12Co涂层的空蚀和磨损性能研究

采用国际上最新的活性燃烧高速燃气喷涂(AC?HVAF)技术制备出WC?12Co金属陶瓷涂层。涂层的X射线衍射检测表明,涂层制备过程中未出现WC粒子的氧化和脱碳现象,涂层相结构基本保持了喂料粉末状态;对制备涂层进行的旋转圆盘空蚀试验表明,WC?12Co硬质涂层抗泥沙磨损性能出色,磨损量仅为不锈钢的1/10;其耐空蚀性能则相反,不及对比0Cr13Ni5Mo不锈钢;对涂层的空蚀破坏机理做了分析,对沙粒磨损损伤特点做了初步探讨。

HVOF喷涂纳米WC-12Co涂层的性能研究

为促进HVOF喷涂纳米WC–12Co涂层在工业上的应用,采用HVOF喷涂法分别制备了纳米和微米结构WC–12Co涂层。研究了涂层的结合强度,测试了两种涂层的显微硬度及耐冲蚀磨损性能,并利用扫描电镜对喷涂粉末、涂层显微组织、冲蚀表面形貌进行了分析。研究结果表明:两种涂层中纳米涂层显微硬度是普通涂层的1.5倍,最高达到1610HV,纳米涂层中WC颗粒的分布更均匀,冲蚀率是微米级涂层的1/2左右,性能更优越。