Effect of Fe content on microstructure and mechanical properties of Cu-Fe-based composite coatings by laser induction hybrid rapid cladding

To select the proper composition and obtain an overall material?microstructure?property relationship for Cu?Fe alloy, theeffect of Fe content on microstructure and properties of Cu?Fe-based composite coatings by laser induction hybrid rapid claddingwas investigated. Microstructure characterization of the composite coatings was tested utilizing SEM, XRD and EDS. Microhardnessmeasurement was executed to evaluate the mechanical properties of the composite coatings. The results show that for low Fe content,the composite coating presents a feature that Fe-rich equiaxed dendrites are embedded in the Cu-rich matrix. With increasing Fecontent, the Fe-rich particles are dispersed in the Cu-rich matrix. With further increasing Fe content, large amounts of Cu-richparticles are homogeneously dispersed in the interdendrite of the Fe-rich matrix. Correspondingly, the average microhardness of thecomposite coatings increases gradually with the increase of Fe content and the microhardness of Cu14.5Fe83Si2C0.5 coating is muchtwice higher than that of the substrate.

Wear and corrosion resistance of laser-cladded Fe-based composite coatings on AISI 4130 steel

The wear and corrosion resistance of Fe_（72.2）Cr_（16.8）Ni_（7.3）Mo_（1.6）Mn_（0.7）C_（0.2）Si_（1.2） and Fe_（77.3）Cr_（15.8）Ni_（3.9）Mo_（1.1）Mn_（0.5）C_（0.2）Si_（1.2） coatings laser-cladded on AISI 4130 steel were studied.The coatings possess excellent wear and corrosion resistance despite the absence of expensive yttrium,tungsten,and cobalt and very little molybdenum.The microstructure mainly consists of dendrites and eutectic phases,such as duplex（γ＋α）-Fe and the Fe–Cr（Ni）solid solution,confirmed via energy dispersive spectrometry and X-ray diffraction.The cladded Fe-based coatings have lower coefficients of friction,and narrower and shallower wear tracks than the substrate without the cladding,and the main wear mechanism is mild abrasive wear.Electrochemical test results suggest that the soft Fe_（72.2）Cr_（16.8）Ni_（7.3）Mo_（1.6）Mn_（0.7）C_（0.2）Si_（1.2） coating with high Cr and Ni concentrations has high passivation resistance,low corrosion current,and positive corrosion potential,providing a better protective barrier layer to the AISI 4130 steel against corrosion.

Fracture Behaviour of Laser Clad Fe-and Ni-base Alloy Coatings on a Cast Iron under SEMI Loading

Laser cladding technique has been applied to renovate some partially-damaged (or worn) components with Fe, Ni, Co-base alloys, hence to improve their hardness values and wear resistance successfully in previous reports. But for some punching or shearing cast iron dies damaged or worn in automobile manufacture, the renovated surfaces also bear some impact loading. Therefore, a small-energy and multi-impact (SEMI) test was designed to investigate the fracture behaviour of renovated cast iron dies achieved by laser cladding of Fe and Ni-base alloys under SEMI loading to meet above requirement. observations show that the fracture took place in the substrate near to the substrate/coating interface rather than at the interface. The tempering temperature has a great influence on the cycles to fracture of laser-clad samples under SEMl loading, i.e. the low tempering temperature of 300℃ gives a maximum cycle to fracture, while a higher tempering temperature of 400℃ has a minimum. Furthermore, the fracture mechanism has also been discussed in present study

Fabrication of Ni34.1Fe27.9B18Si18Nb2 amorphous matrix coating on mild steel by laser processing

Ni34.1 Fe27.9B18 Si18 Nb2 coating was deposited on mild steel substrate using high power laser cladding followed by laser remelting process. The laser processing was conducted by the powder feeding method using low purity materials without shielding box. To learn the surface amorphous matrix coating forming mechanism, the coating without remelting process was also studied. The phases and microstructures were analyzed by X-ray diffraction （XRD）, scanning- and transmission-electron microscopy（ SEM, TEM）. The microhardness and corrosion resistance property of the coating were also measured. The results of SEM, XRD and TEM analysis show that the remelted coating has an amorphous matrix layer embedded with some crystals due to high cooling rate during remelting process. The crystals phases are identified as Fe2 B phase, γ （Fe, Ni ） phase and α- Fe phase. No oxidation phases are found in the coating surface. Hardness profiles reveal microhardness more than 1 100 HVo.5 over the full depth of the amorphous matrix layer, while the unremtled coating and the substrate show relatively lower hardness than the remelted layer. Corrosion resistance tests exhibit that the remelted coating is nobler than the unremelted coating and the substrate material.

激光熔覆WC/Fe梯度涂层对40Cr合金钢抗磨损性能的影响

利用ND-YAG激光器对40Cr钢进行表面熔覆WC增强铁基复合涂层,并且对比了单层激光熔覆、多层激光熔覆及梯度激光熔覆工艺制备的复合涂层的耐磨损性能。对比复合涂层分别为单层50%WC/Fe熔覆涂层、3层50%WC/Fe熔覆涂层、10%WC/Fe+30%WC/Fe+50%WC/Fe梯度涂层。对涂层的微观组织结构、显微硬度和耐磨性能进行了分析。讨论了不同晶粒的形成和生长机制,阐述了WC颗粒对涂层耐磨性能的影响机制。结果发现,与单层铁基WC熔覆涂层相比,多层铁基WC熔覆涂层展现出优异的抗磨损性能,其中,梯度涂层具有更高的硬度、耐磨性和较高的摩擦系数。

Cu-Sn/Fe合金粉末激光熔覆层的组织与硬度分析

为改善Cu基合金涂层与16Mn钢基体的匹配性,提高涂层强度和硬度,采用同步送粉技术,通过工艺优选,在16Mn钢表面激光熔覆了Cu-Sn/Fe基混合合金粉末,并研究了制备的熔覆层组织、颗粒物的相结构、尺寸和弥散分布行为。结果表明,激光熔覆层为树枝晶组织和网状组织及其上分布的σ-FeCr球形颗粒相。颗粒相σ-FeCr对提高熔覆层硬度起到一定的作用。熔覆层、热影响区和基体中,熔覆层硬度最高,进入基体后,硬度值突降,故熔覆层起到表面强化的作用。

超高速激光熔覆Fe-Cr-B基耐磨涂层工艺优化及性能研究

使用超高速激光熔覆在45钢表面制备了Fe-Cr-B基耐磨涂层。采用正交实验研究了激光功率、扫描速度和送粉速度对单道熔覆层宽高比和裂纹的影响,并研究了搭接率对熔覆层表面质量的影响。结果表明,适宜的工艺参数为:激光功率2 300 W、扫描速度250 mm/s、送粉速度24 g/min、搭接率70%,此工艺参数下涂层硬度在754HV_(0.2)到831HV_(0.2)之间(是基体硬度的2.36~2.60倍),在相同条件下铁基涂层的体积磨损量仅为电镀硬铬镀层的3.64%。

激光功率对Fe基涂层组织性能影响的研究

利用激光熔覆技术在45钢基材上制备了不同激光功率下的Fe基合金涂层,研究了不同激光功率对涂层组织性能的影响规律和原因。通过XRD观察涂层物相的变化、金相显微镜观察涂层表面结构、维氏硬度计测试涂层硬度、摩擦试验机检测涂层耐磨性从而得出最佳参数。试验结果表明:涂层组织均致密均匀;涂层主要由Fe和Gr组成,Fe-Cr固溶体形成了具有良好耐腐蚀性和高硬度硬质相相结合的熔覆层,同时具备了较高硬度和耐腐蚀性;不同激光功率下的熔覆层硬度均远高于基材硬度,其中当激光功率为2000W时,熔覆层平均硬度达到567.4HV_(0.2)约为基材的2.5倍;激光功率2000W对应的熔覆层磨损率为1.31×10^(-6)g/(N·m)。综合以上试验分析得出当激光功率为2000W时,熔覆层的表面综合性能达到最优值。

激光熔覆铁基合金涂层的研究进展

激光熔覆技术作为一种先进的材料表面改性技术,具有加工效率高、涂层稀释率低且与基体结合强度高、自动化程度高、环境友好等优点。在各类熔覆材料中,铁基合金在成分上与钢铁材料最为接近,且其成本相对较低,近年来在设备零部件表面强化和再制造领域得到广泛应用。结合国内外最新相关研究成果,从材料体系、工艺参数、外场辅助技术等方面对激光熔覆铁基合金涂层的研究进展进行了综述。总结了熔覆材料的选材依据以及铁基自熔性合金粉末、不锈钢粉末、铁基非晶合金粉末、铁基复合粉末等各类材料的特点和应用。系统讨论了激光功率、扫描速度、光斑直径、送粉速率等工艺参数对铁基涂层成形质量和微观组织及性能的影响机制,并介绍了工艺参数优化在高质量熔覆层制备中的应用。同时,论述了超声振动、电磁场、温度场等外场辅助技术在激光熔覆铁基合金涂层中的应用,阐明了外加能场对激光熔覆过程中熔池及凝固组织的作用机理。最后对激光熔覆铁基合金涂层未来的发展方向进行了展望。

激光熔覆高耐蚀Fe基固溶体合金涂层

Fe基非晶合金具有优异的机械性能与耐蚀性。采用激光熔覆技术在304L不锈钢基体表面熔覆Fe-Cr-Ni-Co-B非晶粉末涂层,利用X射线衍射仪、光学显微镜、扫描电镜和电化学测试系统研究了涂层组织及耐蚀性能。研究结果表明,涂层组织涂层均匀、致密,无裂纹、气孔等缺陷。结合区为平面晶和柱状晶、熔覆层为"丝条状"树枝晶。熔覆层各区域由于成分和冷却速度的差异,致使树枝晶的大小和生长方向明显不同。涂层主要由Fe_(64)Ni_(36)和(FeCrNi)固溶体组成。熔覆层硬度分布较为均匀,涂层平均硬度约为480HV_(0.2),约是304L不锈钢基材的2.5倍。熔覆层的腐蚀电位高于304L基材,自腐蚀电流密度小于304L基材,具有较强的耐蚀性。

激光熔覆Fe基TiC涂层的组织与性能

采用激光熔覆方法在45#钢基体上制备含TiC质量分数为20%~50%的Fe基TiC复合涂层。分别用扫描电镜（SEM）、能谱仪（EDS）、X线衍射（XRD）、显微硬度计、摩擦磨损机对熔覆层的微观组织、物相、硬度及耐磨性进行研究。结果表明：当TiC质量分数为30%时,涂层组织致密,TiC颗粒分布均匀、部分溶解、尺寸减小;涂层主要是由α-Fe固溶体,Fe C,Fe B,B4C,B4Si,Cr5B3,Ti B以及未溶解的TiC等组成;当TiC质量分数为30%时,熔覆层平均维氏硬度为783.8,磨损率为45#钢基体的1/38。

激光熔覆Fe_p/Cu复合涂层组织特征及其形成机理研究

利用２ｋＷ的ＣＯ２气体激光器在Ｑ２３５钢表面熔覆Ｃｕ＋５％Ａｌ混合粉末，获得了外观质量良好的熔覆层。ＳＥＭ观察发现，熔覆层中有圆形颗粒存在，且有规律分布。成分分析表明，颗粒为富Ｆｅ相。提出一个激光熔覆模型对颗粒形成过程进行了解释。

激光熔覆Fe-Al复合涂层组织及性能研究

采用粉末预置法,在Q235钢表面激光熔覆Fe-Al复合涂层。采用SEM、XRD等方法分析了涂层的显微组织和物相结构,研究了不同激光工艺参数对涂层显微硬度和耐磨性的影响。结果表明,在优化工艺参数下,涂层与基体形成了良好的冶金结合,组织均匀细密,涂层中含有Al2O3硬质颗粒相及金属间化合物Fe3Al,其硬度和耐磨性得到提高。

铝合金表面激光熔覆 Fe- Al青铜合金层的组织结构

研究了铝合金表面激光熔覆 Ｆｅ Ａｌ青铜层的组织结构， 结果表明， 熔覆层的组织结构为孪晶结构的 α Ｃｕ＋ 颗粒状（ Ｃｕ， Ｆｅ， Ｓｉ）９ Ａｌ４ （γ１ ）＋ 少量的 Ｃｕ３ Ａｌ（β）， 硬质点相强化、孪晶强化、细晶强化和固溶强化的共同作用使得熔覆层的维氏硬度达到了 ３ ０００ Ｍ Ｐａ～３ ５００ Ｍ Ｐａ， 明显高于其名义硬度 １ ８００ Ｍ Ｐａ～２ １００ Ｍ Ｐａ。同时， 分析了熔覆层相结构的形成原因。

铝青铜合金粉末涂层制备中Fe元素的扩散特性

利用等离子喷焊和激光熔敷技术,将铝青铜合金粉末涂敷在45#钢表面,通过对涂层金相组织观察、界面金相观察、X-ray分析、表面EDS分析、对Fe元素的EPMA分析,研究Fe元素在铜合金涂层中的扩散特性.结果表明,采用等离子喷焊技术制备的涂层中,Fe元素从基材到合金涂层有较强烈持续的扩散过程;采用激光熔敷技术制备的涂层中,Fe元素在基体与合金涂层之间无明显的扩散现象.可见,Fe元素在等离子喷焊层中扩散率较高,在激光熔敷层中扩散率较低.

机械振动辅助激光熔覆Fe-Cr-Si-B-C涂层的显微组织及界面分布形态

采用机械振动辅助激光熔覆复合改性新工艺,在45钢表面制备了单道Fe-Cr-Si-B-C合金涂层。借助X射线衍射（XRD）、扫描电镜（SEM）和能量分散谱（EDS）分析了熔覆层的物相组成、微观结构和元素分布,通过HVS-1000型显微硬度计测试了熔覆层的显微硬度。结果表明,熔覆层主要由α-（Fe,Cr）固溶体、M7C3（M=Fe、Cr）碳化物、Fe2B硼化物和少量Fe0.9Si0.1组成。在机械振动辅助作用下,熔覆层结合界面组织由平面晶向带状和柱状晶转变,振幅为0.13-0.18mm时的晶粒细化效果最为明显;熔覆层中增强相形态随着频率的增加由短杆状向颗粒状、层状、条状转变,分布形态由杂乱分布向弥散分布和网状分布转变。相比未加机械振动的熔覆层,机械振动下的熔覆层中气孔、裂纹减少,显微硬度提高了约13.9%。这些结果显示熔覆层中显微组织形态及其分布主要受振幅和频率协同作用的影响。

激光熔覆原位合成αFe(Al)/Fe_3Al涂层的研究

通过寻求工艺参数与Fe 2 8% (at)Al粉末的最佳匹配 ,利用激光熔覆和复合材料原位合成技术 ,制备了熔覆质量好的α Fe(Al) /Fe3Al涂层。该熔覆层为α Fe(Al)固溶体胞状组织基体上分布着黑色DO3结构Fe3Al质点 ,多数质点分布在晶界上 ,颗粒尺寸为 (10 0～ 30 0 )nm。EDAX线扫描结果表明 ,Al、Fe在整个涂层中分布比较均匀 ,无宏观偏析 ;Al、Fe成分在近界面及界面处缓慢过渡 ,涂层和基体发生互扩散 ,为冶金结合。熔覆层的显微硬度为 6 39HV0 2 ,比基体高 2倍 ,多道搭接处理对熔覆层的硬度影响不大。

激光熔覆Cr_3C_2/Fe复合涂层的组织与磨损性能

采用5kWCO2连续激光器在低碳钢表面激光熔覆Fe基合金涂层(Fe55)及添加20%Cr3C(2质量分数)的Fe基合金复合涂层(Cr3C2/Fe),研究了两种涂层的组织结构、显微硬度及耐滑动磨损性能。结果表明,Fe55涂层以亚共晶方式结晶,在初生柱状固溶体枝晶间存在大量的网状共晶组织。Cr3C2/Fe涂层中Cr3C2大部分溶解,原Fe55涂层中初生柱状固溶体枝晶产生等轴化,枝晶组织也明显细化。激光熔覆Fe55涂层主要由α-Fe和Cr23C6组成,Cr3C2/Fe涂层的主要组成相为γ-Fe;α-Fe,Cr23C6以及未熔Cr3C2。激光熔覆Cr3C2/Fe涂层的硬度和耐磨性明显优于Fe55涂层。

激光-感应复合熔覆Cu-Fe合金涂层的结构与性能

采用激光-感应复合熔覆方法,在黄铜基材表面制备Cu-Fe合金涂层,研究涂层的显微组织与性能特征。结果表明,当激光扫描速度为3000 mm/min、粉末流量为110 g/min时,在黄铜基材上获得表面较光滑、无气孔与裂纹的Cu-Fe合金涂层。另外,Cu-Fe合金在激光-感应复合熔覆过程中发生液相分离,在涂层底部,过饱和的金属基体α-Fe呈平面状与柱状枝晶生长;在涂层中上部,直径不等的球状颗粒α-Fe镶嵌在过饱和的金属基体ε-Cu内,许多细小的白色粒状物ε-Cu在球状颗粒α-Fe内均匀弥散析出,涂层的平均显微硬度相对于基材的提高约2.8倍。

基于工业合金激光熔覆制备Fe基非晶涂层

以FeCoCrMoCBY块体合金为熔覆材料,采用激光熔覆在低碳钢表面制备非晶涂层,探讨不同激光功率对涂层成形及组织的影响,通过显微硬度仪、电化学工作站测试涂层显微硬度及耐腐蚀性能。研究结果表明,其他参数不变,激光功率为17.6~20.8 W时,涂层成形良好,与基材呈典型冶金结合。随激光功率增加,涂层稀释率升高,裂纹倾向增大,非晶化程度降低。激光功率为17.6 W时,涂层主要由非晶组成,稀释率低于24.2%,结构致密,包括热影响区、熔合区和熔覆区;涂层平均显微硬度为1 330HV,约高于基材9倍,在3.5%NaCl溶液中的耐腐蚀性能明显优于316L不锈钢。