铝材表面激光熔覆Ni_(1.5)Co_(1.5)FeCrTi_x高熵合金层的组织与性能

为了提高铝合金的耐磨性及耐蚀性并降低高熵合金中元素偏析的现象,采用CO_2激光熔覆技术在铝基体表面制备了Ni_(1.5)Co_(1.5)FeCrTi_x高熵合金熔覆层。借助光学显微镜、扫描电镜、X射线衍射仪和电化学工作站检测技术研究了Ti含量对Ni_(1.5)Co_(1.5)FeCrTi_x熔覆层显微组织和耐蚀性能的影响。结果表明:Ni_(1.5)Co_(1.5)FeCrTi_x高熵合金熔覆层主要相结构为简单的面心立方相、金属间化合物相和Laves相;当Ti含量摩尔比从0.5增至2.0时,Ni_(1.5)Co_(1.5)FeCrTi_x高熵合金熔覆层的表面硬度从510 HV增加到554 HV,在0.5 mol/L HNO_3溶液中具有优异的耐蚀性能。     

激光熔覆Co1.5CrFeNi1.5Ti0.75Nbx高熵合金的组织和性能研究

目的 研究Nb含量对高熵合金Co1.5CrFeNi1.5Ti0.75Nbx熔覆层组织和性能的影响.方法 在H13钢表面制备了Co1.5CrFeNi1.5Ti0.75Nbx(x=0.25,0.50,0.75,1.00,原子数分数)高熵合金熔覆层,研究Nb含量对熔覆层的物相组织、微观结构、硬度和耐磨性的影响.结果 高熵合金熔覆层主要为BCC相、FCC相和Laves相的组织.在熔覆层中添加Nb,Laves相随之增加,组织的微观形貌发生变化.熔覆层的硬度远远高于H13钢(退火态),Co1.5CrFeNi1.5Ti0.75Nb0.5熔覆层的平均硬度最高,约为H13钢(退火态)的2.8倍.Co1.5CrFeNi1.5Ti0.75Nb0.5熔覆层的摩擦磨损失重最小,磨损程度更低,耐磨性更好.结论 Nb元素加入高熵合金体系会形成Laves相,Laves相能够提高高熵合金的力学性能.相关结果 对于高熵合金体系的研究具有一定意义,为高熵合金的成分设计和优化提供了必要的实验支持.     

添加碳化钨和石墨改善真空熔覆Ni-Co基合金涂层的极化行为

采用真空熔覆技术在45#钢表面制备了不同Co含量的Ni-Co基合金熔覆层及Ni-Co+WC、Ni-Co+WC+Graphite复合熔覆层,研究了涂层在3.5%NaCl溶液中的电化学行为。结果表明,在ZG45表面制备的Ni-Co基合金熔覆层的自腐蚀电位随Co含量的增加而升高,其自腐蚀电位相比ZG45至少提高了4.98%,腐蚀电流则降低了74.93%。在Ni-Co基合金熔覆层中添加WC和石墨(G)后其自腐蚀电位提高:同时添加WC和G时的自腐蚀电位相比只添加WC时提高了32.39%,腐蚀电流则降低了19.37%;且同时添加WC和G试样的自腐蚀电位比Ni-40%Co提高33.86%,耐腐蚀性能相比Ni-Co基合金得到了增强和改善。另外,在同时添加WC和G的试样的极化曲线上出现了钝化区,且其钝化区腐蚀电位宽度大于只添加WC的试样,说明前者的耐腐蚀性优于后者。     

45钢表面Ni基激光熔覆层的耐蚀性能

为改善45钢表面的力学性能和耐蚀性,在相同功率下采用不同扫描速率在其表面激光熔覆制备了Ni基(Ni35A)复合涂层。利用金相显微镜、X射线衍射仪、显微硬度计和电化学腐蚀测试系统对熔覆试样进行组织形貌、相组成、显微硬度和耐蚀性能分析。结果表明:熔覆试样由熔覆层、结合区和基体3部分组成;熔覆层组织细密并与基体冶金结合,扫描速率过大时易形成裂纹;熔覆层主要由FeNi3和Ni3B相组成,不同速率所得熔覆层显微硬度均超过400 HV;扫描速率为500 mm/min时熔覆试样自腐蚀电位提高了40 mV。     

Mo含量对CoCrFeNiMo高熵合金组织及耐蚀性能的影响

高熵合金由于具有优异的机械性能及耐蚀性能在涂层工业领域备受关注。采用同步送粉激光熔覆技术在Q235钢表面制备了CoCrFeNiMo_x高熵合金涂层,研究了涂层的组织结构和耐蚀性能,并结合第一性原理计算分析了涂层耐蚀机理。研究结果表明：CoCrFeNiMo_0.1、CoCrFeNiMo_0.2高熵合金涂层是由fcc相组成,而CoCrFeNiMo_0.3高熵合金涂层则由fcc相和σ相组成。合金的晶粒主要呈树枝晶,枝晶间富集Cr、Mo元素,枝晶内富集Co、Fe元素。在3.5%(质量分数)NaCl溶液中,CoCrFeNiMo_x高熵合金涂层具有优良的综合耐蚀性能;并且随着Mo元素含量的增加,涂层的腐蚀电位正移,腐蚀电流密度减少,钝化区间变长,阻抗弧半径增大,电极反应阻力增强。通过第一性原理计算证明,涂层较高的耐蚀性能与表面致密的钝化膜形成密切相关。     

B_4C加入量对氩弧熔覆Ni-Cr-W合金涂层组织及耐蚀性能的影响

为改善Ni基合金涂层的组织及耐蚀性,采用氩弧熔覆技术在40Cr钢基体表面制备Ni-Cr-W基/B_4C复合涂层,主要研究了B_4C加入量对涂层显微组织、显微硬度以及耐蚀性能的影响。结果表明:合金涂层显微组织由平面晶、柱状晶和树枝状晶等组成;当B_4C含量为5%时,涂层熔覆层的组织明显发生细化;当B_4C含量超过5%时,熔覆涂层表面出现气孔和裂纹等缺陷,内部夹杂增多,涂层质量下降;B_4C的加入提高了合金涂层的硬度,当B_4C含量达到5%时表面硬度较高,达到1 027.4 HV_(0.5N),B_4C含量继续升高,硬度变化不大;B_4C的加入降低了熔覆层耐蚀性,当B_4C含量为5%时耐蚀性相比未加B_4C时的下降不多,耐蚀性较好。     

FeCrMnNiTix高熵合金在NaCl溶液中的腐蚀行为研究

将Fe,Cr,Mn,Ni和Ti 5种金属纳米粉体经行星式球磨机混合后,采用真空熔铸法制备FeCrMnNiTi,FeCrMnNiTi_0.5,FeCrMnNi 3种高熵合金。为研究这3种合金在NaCl溶液中的腐蚀行为,运用电化学工作站测定3种合金在质量分数为3.5%的NaCl溶液中的开路电位、极化曲线和交流阻抗,利用金相显微镜和扫描电镜对腐蚀后的合金进行微观组织观察。电化学测试结果表明:当FeCrMnNiTi合金的自腐蚀电位为-0.301 V时,FeCrMnNiTi_0.5合金的自腐蚀电位为-0.443 V;腐蚀产物形貌观察表明:FeCrMnNiTi_0.5以晶界腐蚀为主,另外2种合金以点蚀为主。由此得出结论:FeCrMnNiTi耐蚀性最好,FeCrMnNiTi_0.5耐蚀性最差;加入Ti可能造成了合金晶格畸变。     

45钢表面激光熔覆CoCrNi中熵合金涂层组织与性能

为探究CoCrNi中熵合金在激光熔覆领域中的应用,以CoCrNi合金粉末作为熔覆粉末,在45钢表面采用同轴送粉法制备合金涂层。利用扫描电镜、X射线衍射仪、显微硬度仪、摩擦磨损实验机和电化学工作站等设备研究了熔覆层微观组织、硬度、耐磨性和耐腐蚀性能。结果表明：熔覆层成形良好,组织均匀致密,组成相主要为FCC单相固溶体;熔池与基体交界处为平面晶,底部靠近中心为柱状晶,顶部分别为胞状晶和等轴晶,3种元素在熔覆层深度方向上的比例几乎相同;熔覆层平均硬度为250HV,摩擦系数、磨损量较基体分别降低了11.7%和36.7%;自腐蚀电流密度略有降低,CoCrNi熔覆层的钝化区域为-150到1 100 mV,表明熔覆层显著提高45钢的耐腐蚀性能。     

含Ce的CuCrZr合金退火前后在氯化钠溶液中的电化学性能

退火作为工业上控制和改变金属材料组织、结构和性能的重要手段,在生产中具有很重要的意义.采用电化学工作站研究了含稀土Ce的CuCrZr合金退火前后在氯化钠溶液中的电化学性能.结果表明,稀土元素Ce的添加有利于提高合金的耐蚀性.对于未退火的研究试样,Ce的添加降低了合金的腐蚀电流;而对于经过退火处理的试样,退火增加了合金在氯化钠溶液中的腐蚀电流,但Ce对耐蚀性的提高作用依旧存在,它的存在可减缓退火对合金耐蚀性的降低作用.同时,试样在1 mol/L NaCl水溶液中的阻抗谱表明:退火提高了试样表面产物膜的致密度,增加了腐蚀反应的难度.     

激光熔覆Al_xCrFeCoCuNi高熵合金涂层的显微组织与性能研究

采用CO2激光熔覆技术在AISI 1045钢基底上制备了Al_xCrFeCoCuNi涂层。通过改变Al的含量来研究其对显微组织和耐磨性能的影响。涂层的微观结构、化学成分和相结构分别通过扫描电镜、能谱和X射线衍射进行了分析。研究结果表明,Al_xCrFeCoCuNi高熵合金涂层主要包括熔覆层、结合区和热影响区。熔覆层和基底具有很好的冶金结合。熔覆层主要由等轴晶和柱状晶组成。XRD分析可知,由于高熵效应使得Al_xCrFeCoCuNi高熵合金涂层相结构主要为简单面心和体心立方结构。Al_xCrFeCoCuNi的表面硬度最高可以达到758Hv,是基底的3倍,而且显微硬度随着Al含量的增加而升高。Al含量高的涂层具有高的硬度,从而提高了耐磨性能。     

Synthesis and characterization of FeCoNiCrCu high-entropy alloy coating by laser cladding

The influences of Si (1.2 mol.%), Mn (1.2 mol.%) and Mo (2.8 mol.%) additions on the microstructure, properties and coating quality of laser cladded FeCoNiCrCu high-entropy alloy coating have been investigated. The multi-component alloy coating is found to be a simple face-centered cubic (FCC) solid solution with less component segregation and high corrosion resistance, microhardness and softening resistance properties. For the coating without Si, Mn and Mo additions, the microstructure is mainly composed of columnar and equiaxed grains with uniformly distributed alloying elements. The microhardness reaches 375 HV_0.5, which is about 50% higher than that of the same alloy prepared by arc melting technique. But the coating quality is very poor. While for the coating with Si, Mn and Mo additions, the coating quality is greatly improved, the microhardness increases to 450 HV_0.5, but the microstructure transforms to dendrite due to a slightly increase in component segregation.     

Electrodeposition and mechanical and corrosion resistance properties of Ni-W/SiC nanocomposite coatings

Ni-W/SiC nanocomposite coatings with various contents of SiC nano-particulates were prepared by electrodeposition in Ni-W plating bath containing SiC particulates. The influences of the SiC nano-particulates concentration, current density and stirring rate of the plating bath on the composition of the nanocomposite coatings were investigated. The surface morphologies of the Ni-W alloy and Ni-W/SiC nanocomposite coating were observed using a scanning electron microscope (SEM). The morphology of Ni-W/SiC nanocomposite coating is smoother than that of Ni-W alloy coating. The microhardness of composite coatings increases with the increasing content of the SiC nano-particulates in the coatings. The corrosion behavior of Ni-W alloy and Ni-W/SiC nanocomposite coatings was evaluated by the anodic polarization curves in 0.5 mol/L NaCl solution at room temperature. It shows that Ni-W/SiC nanocomposite coating has better corrosion resistance than the Ni-W alloy coating.     

On the microstructure and erosion–corrosion resistance of AlCrFeCoNiCu high-entropy alloy via annealing treatment

As-cast AlCrFeCoNiCu high-entropy alloy (HEA) was a solid solution of body-centered cubic (BCC) and face-centered cubic phases with a typical dendrite and interdendrite structures. The precipitated intermediate phases in 600°C annealed HEA are responsible for the improved hardness. After 1000°C annealing treatment, the crystalline was re-arranged because of the decomposition of BCC phases. The 1000°C annealed HEA has the best corrosion resistance due to its re-arranged crystalline structure. Meanwhile, the 600°C annealed HEA has the best erosion–corrosion resistance for its highest hardness and its wear rate is more than two times lower than that of AISI 304 stainless steel. Therefore, the HEA has a potential application in saline–sand slurry because of its superior corrosion and erosion–corrosion resistance.     

High‐Performance Microwave‐Derived Multi‐Principal Element Alloy Coatings for Tribological Application

The authors report the development of Al_xCoCrFeNi (x = 0.1 to 3) high entropy alloy (HEA) coatings using a simple and straightforward microwave technique. The microstructure of the developed coatings is composed of a cellular structure and diffused interface with the substrate. The microstructure of the HEA coatings varies as a direct function of Al content. An increase in Al fraction shows structural transformation from FCC to BCC along with the evolution of σ and B₂ as the major secondary phases. The diffusion of Mo from the substrate enhances the mixing entropy and promotes σ‐phase formation. The HEA coatings show significantly high hardness compared to SS316L substrate steel (227 HV) with a maximum value of 726 HV observed for three‐molar composition. The fracture toughness exhibits an inverse correlation with the Al fraction with the highest value of around 49 MPa m^1/2 observed for Al_0.1CoCrFeNi coating. The equimolar coating composition shows lowest erosion rates among all the tested samples due to optimum combination of the mechanical properties. The erosion resistance of the equimolar coating is 2 to 5 times higher than steel substrate and around 1.5 times higher than the non‐equimolar counterparts depending upon the impingement angles.

     

Deposition and corrosion behavior of silicate conversion coatings on aluminum alloy 2024

Potassium silicate was deposited on AA2024 aluminum alloy as environmentally friendly conversion coatings and its corrosion behavior were examined by means of electrochemical impedance spectroscopy, potentiodynamic polarization and surfaces techniques. Potentiodynamic polarization curves show significant decrease in corrosion current density of silicate coated aluminum in NaCl solution. The corrosion resistance was increased with increasing silicate concentration of coating baths. The results indicated that the coating applied from 3 molar silicate baths is more uniform and continuous. The X‐ray diffraction (XRD) and energy discharge spectroscopy (EDS) spectra confirm the existence of silicate film on the AA2024 surface. The coating performance was evaluated in acidic and basic NaCl solution and the results show the stability of silicate conversion coating in these solutions.     

热浸镀新型高耐蚀锌合金镀层的成分设计及试验研究

为了开发出低成本高耐蚀性合金镀层,通过对新型合金镀层成分进行正交试验设计,在冷轧钢板、热轧钢板及角钢表面通过热浸镀制备不同成分的锌合金镀层,对镀层的锌液流动性、锌灰质量、可镀性、耐蚀性进行了试验研究。结果表明:添加Mg、Ni、Al和V的合金镀层耐蚀性普遍优于传统镀锌和镀Zn-Ni-V合金镀层,Mg对于耐蚀性的影响最显著,Al和Mg元素对合金镀层可镀性的影响最大,在试验含量范围内Ni和V含量对合金镀层可镀性的影响不显著,新型高耐蚀性锌合金镀层成分中各元素的优化水平组合为Mg含量0.3%~0.5%,Al含量≤0.02%,Ni含量0.06%、V含量0.04%。     

激光熔覆高熵合金涂层的研究进展

高熵合金涂层具有的良好热稳定性、耐高温性能使其成为高温涂层科学领域一个新的研究热点。激光熔覆技术制备高熵合金涂层的方法是获得其优越性能的制备方法之一。本文主要从涂层成分设计、组织结构、退火工艺与性能、耐高温氧化性能以及其他性能等方面综述了激光熔覆技术制备高熵合金涂层的最新研究成果,分析了当前激光熔覆技术制备高熵合金涂层存在的问题,提出了应从组元设计、基础理论、性能规律及加工工艺等方面完善科学研究体系,以期制备出性能优异的高熵合金涂层。     

高频脉冲电镀制备Ni—Co／SiC复合镀层及性能研究

采用高频脉冲电源,在镍钴合金衬底上添加SiC,探索制备镍钴合金碳化硅镀层的最佳条件。较佳工艺条件为：频率80kHz,平均电流密度3A／dm^2,占空比0．24,温度为40摄氏度,添加剂为0．5g／L煮沸30min的十二烷基硫酸钠与1g／L糖精钠。通过SEM、XRD测试结果分析高频脉冲各条件对镀层性质的影响原因,研究了脉冲频率、占空比、电流密度、SiC及添加剂对镀层结构、耐腐蚀性的影响。相比相同条件下未添加SiC的镍钴合金镀层,高频脉冲镀层的孔隙率较低,表面致密均匀,耐腐蚀性较好,高频脉冲电镀Ni-Co／SiC合金镀层的耐腐蚀性随着频率的升高而显著增强。