Structure and mechanical properties of thick Cr/Cr_2N/CrN multilayer coating deposited by multi-arc ion plating

A Cr/Cr2N/CrN multilayer coating with a thickness of 24.4 μm was deposited by multi-arc ion plating. The coating was systematically characterized by field emission scanning electron microscopy(FESEM), X-ray photoelectron spectrometry(XPS), energy dispersive spectroscopy(EDS), X-ray diffraction(XRD) and transmission electron microscopy(TEM). Hardness and adhesion were tested by nanoindentation and scratch tester, respectively. The friction properties were investigated by a reciprocating UMT-3MT ball-on-disk tribometer in air and seawater. The results showed that the multilayer coating consisted of three different layers, with Cr,Cr2N and CrN phases, respectively. Compared with CrN single layer coating, the adhesion of the multilayer coating was improved significantly, the hardness of the multilayer coating was(21±2) GPa. The corrosion resistance of the multilayer coating was also improved in artificial seawater. The friction coefficient of multilayer coating was lower than that of CrN single layer coating both in air and seawater.

Microstructure and indentation toughness of Cr/CrN multilayer coatings by arc ion plating

Cr/CrN multilayer coatings with bilayer periods in the range from 1351 to 260 nm were prepared on 304 stainless steel substrates by arc ion plating to study the microstructure and properties of multilayer coatings and stimulate their application.SEM results confirm the clear periodicity of the Cr/CrN multilayer coatings and the clear interface between individual layers.XRD patterns reveal that these multilayer coatings contain Cr,CrN and Cr_2N phases.Because Cr layer is softer than its nitride layer,the hardness decreases with the shortening of the bilayer period(or increasing volume fraction of Cr layer).The Cr/CrN multilayer coating with 862 nm period possesses the highest indentation toughness due to a proper individual Cr and nitride layer thickness.However,for the Cr/CrN multilayer with the bilayer period of 1351 nm,it possesses the lowest toughness due to more nitride phase.The indentation toughness of Cr/CrN multilayer coatings is related with their bilayer period.A coating with a proper individual Cr and nitride layer thickness possesses the highest indentation toughness.

TiN/CrN multilayered hard coatings with TiCrN interlayer deposited by a filtered cathodic vacuum arc technique

TiN/CrN multilayered hard coatings with TiCrN interlayer were deposited onhigh speed steel substrates by using a filtered cathodic vacuum arc technique. The structure andcomposition of the coatings were characterized by scanning electron microscopy (SEM) and Augerelectron spectroscopy (AES). A high adhesion of up to 80 N was demonstrated by scratching tests forthe multi-layered coatings. Nanoindentation tests were performed to determine the hardness andelastic modulus of the coatings as a function of the multiplayer modulation period. It was observedthat the hardness of the multilayered coatings is higher than those of either TiN or CrN singlecoatings, and it increases with decreasing modulation periods, which is consistent with predictionsfrom the Hall-Petch type strengthening mechanism, though at small modulation periods, deviation fromthe Hall-Petch relation has been observed for the multilayered coatings. The life-span of drillscoated with TiN/CrN multilayered is triple as long as that coated with TiN layer.

Multilayered gradient CrN/ZrN coatings synthesized by magnetron sputtering

The multilayer gradient CrN/ZrN coatings were synthesized by a dual cathode DC magnetron sputtering.The influence of different species of reaction gases and partial pressures on structure and mechanical properties was investigated using XRD, AES, XPS, and nanoindentation. The results show that N2-NH3 mixture process gas is of benefit to the synthesis of superhard multilayered gradient CrN/ZrN coatings. The presence of the preferred orientations of CrN(111), (200) and ZrN (111), (220) in the structure is a main reason for superhardness of multilayered gradient coatings.

CrN/TiAlN多层涂层的微观结构和摩擦磨损性能

特种装备车辆往往在高速、高冲击等复杂环境下运行,底盘选装密封件表面容易被磨损造成密封失效,在密封工作面制备硬质涂层是提高服役寿命、延长维修周期的重要方法。采用物理气相沉积法在45#钢表面制备单层CrN涂层和不同过渡层厚度的多层CrN/TiAlN涂层,用X射线衍射仪、扫描电子显微镜、表面轮廓仪、纳米压痕仪和往复式摩擦磨损试验机,研究涂层的微观结构、机械性能和摩擦磨损性能。结果表明单层CrN涂层厚度为0.87μm,其硬度和模量最小为19.49 GPa和160.53 GPa。CrN/TiAlN多层涂层的硬度和模量明显提高,且随过渡层厚度增加而增大,4CrN/TiAlN涂层的硬度和模量可达到39.86 GPa和386.72 GPa。在空气环境下的摩擦磨损试验中,单层CrN涂层被快速破坏;CrN/TiAlN多层涂层的平均摩擦因数随着过渡层厚度的增加先增大后减小,最大磨损深度和磨痕截面积不断下降。4CrN/TiAlN涂层具有最优摩擦磨损性能,其平均摩擦因数为0.792 5,磨痕截面积为315.09μm^(2),磨损机理为磨粒磨损和少量粘着磨损。提高过渡层厚度能够降低基体的塑性变形,降低涂层与基体的物理性能差异,减少涂层开裂并提高涂层摩擦磨损性能。通过调控过渡层厚度获得性能优异的CrN/TiAlN多层涂层,研究成果可应用于车辆旋转密封件上,显著提高密封工作面耐磨损性能。

SUS321不锈钢表面Cr/CrN涂层的制备与抗氧化及耐腐蚀研究

采用磁控溅射技术,在SUS321不锈钢表面制备Cr/Cr N涂层,利用扫描电子显微镜(SEM)、X射线衍射仪(XRD)及分析天平等分别表征样品高温氧化及酸性盐雾腐蚀实验后的微结构及增重。结果表明,当磁控溅射气体分压比为P_(Ar)/P_(N_(2))=3∶1的涂层样品抗氧化性能及耐腐蚀性能最佳。在此基础上通过循环沉积制备了多层Cr/CrN涂层,6周期涂层样品在600℃氧化200 h后的单位面积增重为3.599 g/m^(2),表面氧化膜致密,没有出现剥落现象;6周期的涂层样品在酸性盐雾环境中能够保持480 h表面无变化,在放置500 h后边缘部位才开始出现轻微锈迹。固定磁控溅射气体分压比为P_(Ar)/P_(N_(2))=3∶1时,制备的6周期Cr/CrN多层膜涂层具有最佳的抗氧化及耐酸性盐雾腐蚀性能。

Cr-CrN-Cr-CrAlN多层膜对TC4钛合金力学性能的影响

为了提高钛合金基体的表面抗冲蚀性能,并研究Cr基多层膜对钛合金基体的疲劳力学性能的影响,采用真空阴极电弧沉积技术在TC4钛合金表面沉积3.99,6.85,9.62μm 3种厚度的Cr-CrN-Cr-CrAlN多层膜。主要通过拉伸试验和轴向加载疲劳试验,研究对比了室温下TC4钛合金基体与膜层试样的轴向拉伸性能和轴向高低周疲劳性能。结果表明:在TC4钛合金表面所制备的3种Cr-CrN-Cr-CrAlN多层膜的厚度分别约为3.99、6.85和9.62μm,硬度分别为2455、3024和3578 HV,膜基结合力则分别为12.4、15.2和20.1 N。镀多层膜后提高了TC4钛合金的拉伸屈服强度、抗拉强度和弹性模量,而降低了断裂伸长率。经镀6.85μm的多层膜后,TC4钛合金的轴向高周疲劳极限下降了4.15%,镀膜对高周疲劳性能影响较小;而低周疲劳性能影响则较大,50000次寿命对应的疲劳强度降低了约21.04%。

Inconel 718合金表面纳米多层CrAlN/CrN涂层的制备及高温摩擦学性能研究

为提高Inconel 718合金的表面硬度和高温摩擦磨损性能,采用多弧离子镀技术在其表面制备CrAlN/CrN涂层。使用X射线衍射仪(XRD)、X射线光电子能谱仪(XPS)、扫描电镜(SEM)、纳米压痕仪和划痕仪等对涂层的微观结构、力学性能进行分析表征。使用UMT摩擦磨损试验机测试涂层在室温、350℃和650℃下的摩擦性能,并对磨痕的形貌特征、元素分布和物相进行分析,分析涂层在不同温度下的摩擦磨损机制。结果表明:纳米多层CrAlN/CrN涂层微观结构致密,主要由fcc-CrN相组成,择优取向为(200)晶面;CrAlN/CrN涂层在Inconel 718合金表面具有良好的力学性能,其硬度和结合力分别为(29.3±1.2)GPa和70.4 N;涂层在室温和350℃下具有优异的耐磨性,磨损率分别低至1.5×10^(-6)mm^(3)/(N·m)和1.7×10^(-6)mm^(3)/(N·m),主导的磨损机制分别为磨粒磨损和疲劳磨损;650℃时涂层达到最低摩擦系数(0.33),但磨损率有所升高,主要表现为磨粒磨损。

45钢表面TD-Cr/PVD-CrN复合涂层磨蚀性能

目的采用热扩散(TD)渗金属技术和物理气相沉积(PVD)技术对45钢表面进行强化,以提升45钢表面硬度和抗磨蚀性能,延长45钢的使用寿命。方法采用热扩散渗金属技术和物理气相沉积技术制备TD-Cr、PVD-CrN及TD-Cr/PVD-Cr N(Cr/CrN复合涂层)3种涂层。利用扫描电镜(SEM)、X射线衍射仪(XRD)研究涂层的微观形貌、元素分布和物相组成。通过纳米压痕研究涂层的硬度、弹性模量。通过摩擦磨损实验和电化学腐蚀实验,研究涂层的摩擦性能和腐蚀性能。结果TD-Cr、PVD-Cr N、TD-Cr/PVD-Cr N 3种涂层的组织结构均致密均匀,厚度分别为19.78、1.075、32.24μm。TD-Cr/PVD-Cr N涂层的硬度达到28.7 GPa,高于其他涂层,同时,Cr/Cr N复合涂层的弹性模量和弹性恢复能力均优于其他涂层。在盐水环境下,TD-Cr、PVD-Cr N、TD-Cr/PVD-CrN的摩擦因数分别为0.52、0.38、0.35,磨损体积分别为26、0.15、0.05,TD-Cr/PVD-CrN展现出较好的耐磨性能。在盐水环境下,TD-Cr/PVD-CrN涂层的抗腐蚀性能略低于TD-CrN涂层。结论综合看来,TD-Cr/PVD-CrN复合涂层可以有效提升45钢的表面抗磨蚀能力,延长其使用寿命。

Cr-CrN-Cr-CrAlN多层膜厚度对结构和性能的影响

采用电弧离子镀技术在TC4钛合金表面制备不同厚度的Cr-CrN-Cr-CrAlN多层膜,研究了多层膜厚度对其结构及性能的影响。利用扫描电子显微镜、X射线衍射仪、显微硬度计、划痕仪、应力测试仪、砂粒冲蚀试验仪和拉伸试验机检测分析了多层膜的表面及截面形貌、微观结构、硬度、结合力、残余应力、抗砂粒冲蚀性能和拉伸性能等。结果表明:随着多层膜厚度的增加,膜层表面颗粒增多,表面质量略有下降,择优取向由(200)晶面逐渐向(111)晶面转变;随着厚度的增加,残余应力逐渐增加,膜层硬度、膜基结合力、裂纹扩展抗力先上升后下降,在厚度为10.58μm时达到最佳,其硬度为3404Hv、结合力为58.6N、裂纹扩展抗力为758.49,抗砂粒冲蚀性能提高3倍以上;TC4钛合金表面镀多层膜后,屈服强度和抗拉强度均略有提升,但断后伸长率降低,当膜层厚度为14.50μm时,断后伸长率较基材降低30%,断裂机制由韧性断裂转变为脆性断裂。在一定范围内增加膜层厚度有利于提升性能,但需合理控制其厚度以减小对钛合金基材的负面影响。

电弧离子镀Al-Cr-O/Zr-O+NiCoCrAlSiY和Al-Cr-O+NiCoCrAlSiY涂层的抗氧化性和隔热性能

采用电弧离子镀在高温合金表面沉积Al-Cr-O/Zr-O多层涂层和Al-Cr-O单层涂层+NiCoCrAlSiY结合层,并在1000~1200℃下进行热处理。利用扫描电子显微镜和X射线衍射仪分析涂层的显微组织和物相结构。结果表明,Al-Cr-O/Zr-O多层涂层和Al-Cr-O单层涂层均呈现出致密的球形结构。热处理后,Al-Cr-O/Zr-O涂层表面出现裂纹,且裂纹随着温度的升高而增多和变粗。然而,Al-Cr-O涂层经热处理后其表面胞状结构转变为紧密连接的粒状结构,并且随着热处理温度的升高,粒状结构显著长大。由于作为氧离子导体以及t-ZrO_(2)的致密度低于α-Al_(2)O_(3),Al-Cr-O/Zr-O涂层中的t-ZrO_(2)为氧离子向涂层内扩散提供了通道,因此,Al-Cr-O单层涂层+NiCoCrAlSiY涂层体系的高温抗氧化性优于Al-Cr-O/Zr-O多层涂层+NiCoCrAlSiY涂层体系。但是,由于更大的陶瓷涂层厚度,t-ZrO_(2)相的低热导率以及层间界面的热反射作用,Al-Cr-O/Zr-O多层涂层+NiCoCrAlSiY涂层体系的隔热性能优于Al-Cr-O单层涂层+NiCoCrAlSiY涂层体系。

Tribological behavior of CrN-coated Cr–Mo–V steels used as die materials

DIN 1.2343 and 1.2367 steels are commonly used as die materials in aluminum extrusion, and single/duplex/multi-coatings enhance their surface properties. The design of an appropriate substrate/coating system is important for improving the tribological performance of these steels under service conditions because the load-carrying capacity of the system can be increased by decreasing the plastic deformation of the substrate. In this study, the tribological behavior of CrN-coated Cr–Mo–V steels(DIN 1.2343, 1.2367, and 1.2999 grades) was investigated using different setups and tribological pairs at room and elevated temperatures. The aim of this study was to reveal the wear resistance of a suggested system(1.2999/CrN) not yet studied and to understand both the wear and the failure characteristics of coated systems. The results showed that(i) among the steels studied, the DIN 1.2999 grade steel exhibited the lowest friction coefficient because it had the highest load-carrying capacity as a result of secondary hardening at elevated temperatures;(ii) at room temperature, both abrasive tracks and adhesive layers were observed on the worn surfaces; and(iii) a combination of chemical reactions and progressive oxidation caused aluminum adhesion on the worn surface, and the detachment of droplets and microcracking were the characteristic damage mechanisms at high temperatures.

直管磁过滤弧离子镀CrN涂层改善304不锈钢表面性能研究

采用直管磁过滤弧离子镀在304不锈钢表面沉积CrN单一涂层和Cr/CrN复合涂层,分别运用X射线衍射仪、光学显微镜、显微硬度计、摩擦磨损仪测试分析了其组成结构及复合涂层的表面机械性能。结果表明:直管磁过滤弧离子镀Cr/CrN复合涂层呈现出致密、均匀的表面形貌,且具有高硬度、低摩擦系数等优异的表面机械性能,显著提高了304不锈钢表面的耐摩擦磨损特性。

Cr/CrN多层膜的结构及腐蚀性能研究

利用电弧离子镀设备,在45#钢基体上制备了两种调制比的Cr/CrN多层膜。采用X射线衍射技术(XRD)、扫描电子显微镜(SEM)、电子探针(EPMA)、M273A电化学系统等技术分析了薄膜的相结构、表面形貌、横截面元素分布、模拟海水中的抗腐蚀性能。结果表明:膜层主要由CrN、Cr2N和Cr组成,以Cr2N(111)为择优取向;膜层为Cr层-过渡层-CrN层的"三明治"调制结构;Cr/CrN多层膜结构与中间Cr层的存在可以显著提高基体和单层CrN抗腐蚀性能,45#钢+Cr/CrN(5/10)的防护体系抗腐蚀性能最佳。

TiAlCrN和TiAlCrN/CrN复合膜的微观组织与力学性能

利用离子氮化形成过渡层,通过改变溅射沉积工艺参数,制备了TiAlCrN和TiAlCrN/CrN多层复合膜。采用电子探针(EPMA)、扫描电子显微镜(SEM)、X射线衍射仪(XRD)、纳米压痕仪及微米划痕仪等技术表征两种复合膜的成分结构和力学性能。结果表明:两种膜都是面心立方结构,TiAlCrN膜和TiAlCrN/CrN多层膜分别在(111)和(200)面具有一定的择优取向;TiAlCrN膜的结构和成分都比较均匀,而TiAlCrN/CrN多层膜的结构和成分则呈周期性变化。由于离子渗氮层的支撑作用及氮化物外延生长,TiAlCrN/CrN多层膜的显微硬度(3450HV)高于TiAlCrN膜的(2500HV);两种膜都具有较高的膜基结合力,但TiAlCrN/CrN多层膜的综合力学性能比TiAlCrN膜的更好。

多界面CrN/CrAlN涂层在海水环境中的腐蚀磨损性能研究

目的通过多界面结构CrN/CrAlN涂层来提高316不锈钢在海水中的耐腐蚀磨损性能。方法采用多弧离子镀技术在316不锈钢基底表面制备CrAlN单层和CrN/CrAlN多层涂层。利用扫描电子显微镜(SEM)、透射电子显微镜(TEM)和X射线衍射仪(XRD)等设备表征涂层的微观结构和相组成;借助纳米压痕仪及划痕仪分别测试涂层的硬度和结合强度;通过往复式摩擦磨损试验机及电化学工作站,实时记录涂层在人工海水环境下摩擦系数和电化学信号的连续变化,并采用扫描电子显微镜对磨痕形貌进行分析,评价CrAlN单层和CrN/CrAlN多层涂层在人工海水环境中的腐蚀磨损特性。结果CrN/CrAlN多层涂层结构致密,层间界面清晰,厚度大约在4.12μm,力学性能优异,其硬度高达37.65 GPa。在海水环境中,摩擦系数随外加电位增加而降低,且当外加电位为0.2 V时,最低摩擦系数在0.29左右。而多层涂层损失量变化规律与之相反,当外加电位为–0.6 V时,其具有最低损失量,大约为0.00086 mm^(3)。相比CrAlN单层涂层,CrN/CrAlN多层涂层的腐蚀电流密度降低,损失量显著减小。结论CrN/CrAlN多层涂层具有致密的多界面结构,在海水环境中的耐腐蚀磨损性能更为优异。主要失效机制为磨粒磨损、塑性变形和腐蚀磨损。

活塞环表面Cr／CrN纳米多层膜的微观结构与摩擦学性能

为改善发动机活塞环的摩擦学性能,提高其使用寿命,采用多弧离子镀技术在活塞环表面制备了Cr/CrN纳米多层膜.采用x-射线衍射(XRD)、透射电子显微镜(TEM)、俄歇能谱仪(AES)、纳米硬度仪和CETR摩擦磨损试验机,系统分析了不同调制周期Cr/CrN纳米多层膜的微观结构、成分分布、纳米硬度和抗滑动磨损性能.结果表明:Cr/CrN多层膜由CrN、Cr2N和Cr相组成,在CrN(200)方向上出现择优取向.随调制周期的减小,多层膜的硬度和残余应力增大,当调制周期为80 nm时,多层膜的硬度值最高达到21.5 GPa;当调制周期为120 nm时,H3/E2值达到最高,此时划痕临界载荷值最高.根据摩擦磨损试验结果可知,与电镀Cr和CrN涂层相比,Cr/CrN多层膜具有相对较好的抗滑动磨损性能,其磨损机制主要以磨粒磨损为主,有可能替代原活塞环Cr电镀层.

Al、Ti共掺杂CrN基镀层的结构调变和摩擦学性能

利用闭合场非平衡磁控溅射技术在高速钢基体上制备具有不同结构的CrAlTiN镀层,采用XRD、SEM等手段对镀层微观组织结构进行了分析,并测试了其力学性能和摩擦学性能。结果表明:与传统的硬质镀层CrN、TiN相比,掺杂Al和Ti元素后的四元CrAlTiN镀层,无论形成多层结构,还是共沉积复合结构,都具有良好的力学性能和低的摩擦系数以及高耐磨损性能。

AlN/CrN纳米多层膜的制备及性能的研究

采用多弧离子镀技术制备AlN/CrN纳米多层膜,研究了多层膜调制周期对AlN生长结构的影响以及纳米多层膜的机械性能.结果表明:在小调制周期下AlN会以立方结构存在,并与CrN层形成同结构共格外延生长,使纳米多层膜产生较大的晶格畸变;AlN/CrN纳米多层膜硬度和弹性模量随着调制周期的减小呈现上升的趋势,当调制周期小于8 nm时其增速明显增大,并在调制周期为3.8 nm时达到最高硬度35.0 GPa和最高弹性模量405 GPa;AlN/CrN纳米多层膜的硬度和弹性模量在小调制周期时的升高与c-AlN的产生并和CrN形成的共格结构有关.

CrN与Cr-C-N涂层在海水环境下的微观结构及摩擦学性能

采用离子镀技术在硅片基体上对CrN涂层进行碳元素掺杂得到Cr-C-N三元复合涂层,利用扫描电镜(SEM)、电子能谱(EDS)、X射线光电子能谱仪(XRD)等对其涂层组织形貌及成分进行表征,用摩擦磨损试验仪及电化学工作站测试涂层的磨损及电化学性能。结果表明:对CrN涂层进行碳元素掺杂可得到Cr-C-N三元复合涂层,Cr-C-N中的C元素以硬质碳化物Cr7C3的形式在晶界区域偏聚形成"富碳"骨架网络,力学性能与耐海水腐蚀性能均有明显提升,同时涂层表面也因碳化物偏聚出现微区硬度差异较大的现象,承受载荷时应力不连续状态导致其摩擦因数较CrN涂层有小幅升高,但在大载荷高速滑动时表现出较低的磨损率。