Ti-6Al-4V合金表面激光制备高温耐蚀涂层的研究

以在Ti-6Al-4V合金表面激光制备高温耐蚀涂层为目标,研究了以激光熔覆的方法在Ti-6Al-4V合金基体上合成制备钛铝化物基原位自生TiC颗粒增强的复合材料涂层以及钛-钼系耐蚀钛合金涂层,采用金相显微镜、扫描电镜、X射线衍射仪、显微硬度计等分析了两种涂层的形貌、显微组织、相组成、显微硬度分布等特征.     

激光沉积Ti-6Al-2Zr-Mo-V钛合金高周疲劳性能

 疲劳失效是钛合金工业应用中最重要的失效方式,疲劳强度是钛合金应用的关键性指标。为了研究激光沉积Ti-6Al-2Zr-Mo-V钛合金的疲劳性能和行为,在625 MPa到900 MPa不同应力水平下进行了室温高周疲劳(HCF)测试(应力比R=0.1,加载频率f=120~130 Hz),完成了疲劳断口表面分析。研究了气孔存在及分布对激光沉积Ti-6Al-2Zr-Mo-V钛合金疲劳性能的影响。激光沉积钛合金具有细小α/β片层组织。分析结果显示,虽然疲劳源区有气孔存在,激光沉积Ti-6Al-2Zr-Mo-V钛合金仍然具有优异的疲劳性能。取向丰富细小的α/β片层组织能有效减小疲劳源区滑移长度。分析结果还表明,应力水平对疲劳行为有一定影响。     

Ti-6Al-4V合金氢致塑性效应与应用

利用光学显微镜研究了置氢处理后Ti-6A1-4V合金的微观组织,通过X射线衍射分析试验研究了置氢处理过程中的相转变过程;采用室温压缩试验研究了置氢处理后Ti-6Al-4V合金的变形行为,并进行了冷镦试验.结果表明,氢促进了α"马氏体与亚稳β相的形成,亚稳β相的形成与转变是Ti-6Al-4V合金变形性能提高的主要因素;在...     

粉末冶金Ti-6Al-4V 的组织及形成机理

利用热等静压(HIP)技术及旋转电极粉,采用预合金粉工艺制备了全致密的粉末冶金Ti-6Al-4V合金,用光学显微镜对其金相组织进行了观察,分析其形成机理,并对粉末冶金Ti-6Al-4V合金的室温拉伸性能、弹性模量、冲击性能及断裂韧性进行了研究.结果表明:粉末冶金Ti-6Al-4V金相组织主要由条片α相+相间β相组成,有细小的等轴α相分布在晶粒界面处,包裹着条片α相,这种独特的组织状态是由制备工艺决定的,具有良好的综合性能.     

激光沉积制备Nb3Al基难熔金属间化合物研究

通过控制激光功率使Nb-12Ti-22Al(at%)和Nb-22Al(at%)两种成分配比的混合元素粉末在Ti-6Al-4V基体上激光沉积合成了Nb3Al基难熔金属间化合物,并达到了预期设定的成分配比,其显微组织均匀细小,在δ-Nb3Al基体上分布着不同形态的β-Nbss.在合适的激光功率下,无裂纹的沉积层厚度有一定的限制,随着沉积厚度的增加,沉积层中残余拉应力增大,沉积薄壁件容易在底部发生断裂.由于Ti的添加使Nb-12Ti-22Al的的裂纹倾向性小于Nb-22Al.     

铸造钛合金的氢处理细化晶粒的研究

本文研究了氢处理（渗氢+共析处理+真空除氢）对铸造Ti-6Al-4V合金微观组织的影响。发现Ti-6A1-4V合金渗氢后析出片状的面心立方结构的TiH₂相。随含氢量的增加,TiH₂相趋于球化。渗氢试样经共析处理后,原晶界α消失,组织转变为α+TiH₂共析组织及少量残余β相。真空除氢后,组织变为细小的等轴组织。氢处理提供了一种细化铸造Ti-6Al-4V组织的有效途径。     

Ti-6Al-2Zr-1Mo-1V合金粉末冶金工艺

研究了Ti-6Al-2Zr-1Mo-1V合金预合金粉末经热等静压烧结后的力学性能和显微组织。结果表明，等离子旋转电极粉末氧增量低，粒度分布较集中，颗粒内部组织细小均匀；粉末钛合金材料室温拉伸强度不低于970MPa，伸长率为16％-21％，组织为均匀的条状α相和细小的β转变组织。     

SP700和Ti-6Al-4V钛合金细晶组织的疲劳裂纹扩展特征

研究采用一种新的热机械处理工艺获得的SP700和Ti-6Al-4V钛合金细晶组织的室温疲劳裂纹扩展性能及其疲劳断裂行为.实验结果表明,与Ti-6Al-4V合金相比,SP700钛合金具有更低的疲劳裂纹扩展速率,特别是在较大的△K的情况下.SP700和Ti-Al-4V合金具有基本相同的波浪滑移疲劳断裂特征.     

稀土Y对Ti-23Al-25Nb合金显微组织的影响

采用OM,XRD,XRF,SEM,EPMA,TEM等分析手段研究了稀土Y对Ti-23Al-25Nb合金显微组织的影响.结果表明:两种合金铸态显微组织均为O相;稀土Y明显细化了Ti-23Al-25Nb合金晶粒尺寸,Ti-23Al-25Nb合金的晶粒尺寸在400～600μm之间,Ti-23Al-25Nb-0.36Y合金的晶粒尺寸在40～100μm之间,细化大约6～8倍.通过Ti-23Al-25Nb-0.36Y合金背散射、各元素线分布和TEM分析发现,稀土Y在Ti-23Al-25Nb合金中以Y2O3的形式存在于晶内和晶界,根据O相形成机制和晶粒细化理论,分析了稀土Y细化O相晶粒的过程.     

γ-TiAl金属间化合物合金激光表面合金化组织与摩擦学性能

分别利用预涂活性碳粉和 Ti C粉 2种方法对γ-Ti Al基合金 Ti-4 8Al-2 Cr-2 Nb进行激光表面合金化,制得了无裂纹、表面光滑、内部组织致密、厚度可达 1.6mm以上的、以硬质 Ti C树枝晶为增强相的快速凝固“原位”金属基耐磨复合材料表面改性层,分别采用 OM,SEM,EDS,XRD等方法分析了激光合金化耐磨表面改性层的显微组织,分别在销 -环滑动磨损、Si C纤维刷式高速滑动磨损及微动磨损条件下评价了激光表面改性层的摩擦学性能。结果表明 :采用上述 2种方法所获激光表面合金层组织均匀、与基体间结合为完全冶金结合,合金层硬度及在 3种磨损条件下的耐磨性均大幅度提高。激光表面合金化是提高γ-Ti Al合金摩擦性能的一种很有前途的表面改性方法     

Investigation on surface integrity of electron beam melted Ti-6Al-4 V by precision grinding and electropolishing

Electron beam melting (EBM), as an excellent Additive Manufacturing (AM) technology, enables the printing of Ti-6Al-4 V alloy for a wide range of applications such as aerospace and biomechanical industries. It improves functionality and integrity of components and negates complexities in assembly processes. However, due to the poor surface and sub-surface integrity represented by the rough surface finish and low dimensional accuracy, achieving a favorable surface condition is quite challenging. Therefore, post processing becomes essential for these electron beam melted (EBM-ed) Ti-6Al-4 V alloys. Being the most common technique to improve such parts, milling of Ti-6Al-4 V alloy is very challenging and resulting tool wear issues, due to its unique material properties. Thus, this paper presents a comprehensive study on the surface integrity of EBM-ed Ti-6Al-4 V parts processed by precision grinding and electropolishing, aiming to qualitatively and quantitatively clarify the interrelation between process parameters and processed surface quality. The surface and subsurface characteristics such as profile accuracy, surface roughness, microstructure, defective layer and residual stress before and after post processing were compared and evaluated. The results show that by precision grinding, the profile accuracy was improved from over 300 µm PV to 7 µm PV, while surface roughness (R_a) was reduced from 30 µm to about 2 µm. The layer with partially melt particles was removed, but introduced a deformed subsurface layer with more residual stress. Then by applying electropolishing, the residual stress was released and the deformed layer was removed. In addition, R_a was further reduced to 0.65 µm. The research can serve as a reference for the integration of post machining processes with AM.     

Potentials of manufacture and repair of nickel base turbine components used in aero engines and power plants by laser metal deposition and laser drilling

IntroductionExpensive turbine parts like HPT(HighPressure Turine)blades or vanes are replaced bynew parts in case of damage.For example theburn through of the inner side of a blade or vane(Figure 1)is a frequently appearing damage,which cannot be repaired…     

Experimental study of effect of post processing on fracture toughness and fatigue crack growth performance of selective laser melting Ti-6Al-4V

For Ti-6Al-4V, a titanium alloy increasingly used in aerospace structure, selective laser melting (SLM) is an attractive additive manufacturing technology, which is attributed to its complex construction capability with high accuracy and good surface quality. In order to obtain qualified mechanical properties, SLM parameters and post processing should be tailored for diverse service conditions. Fracture toughness and fatigue crack growth (FCG) behavior are critical characteristics for damage tolerance evaluation of such metallic structures, and they are affected by post processing technologies significantly. The objective of this study is to obtain the fracture toughness and fatigue crack growth behavior of Ti-6Al-4V manufactured by SLM, and to evaluate the influence of post-SLM thermomechanical treatment and surface machining. Fracture toughness and FCG tests were performed for SLM Ti-6Al-4V in three types of post processing status: as-built, heat treated and hot isostatically pressed (HIPed), respectively. Specimens with as-built and machined surface were tested. The microstructure and fractography were analyzed as well in order to investigate the relevance among manufacture process, microstructure and mechanical properties. The results demonstrate that as-built SLM Ti-6Al-4V presents poor ductility and FCG behavior due to martensitic microstructure and residual stresses. Both heat treatment and hot isostatic pressing improve the plane-stress fracture toughness and FCG performance considerably, while surface machining shows slight effect.     

热障涂层的激光表面改性参数优化和结构设计

热障涂层是航空发动机涡轮叶片关键核心技术之一,但在服役条件下常受环境沉积物、熔盐等的腐蚀而过早失效。激光表面改性是一种提高涂层抗腐蚀性能的有效办法,但改性涂层的激光工艺优化和结构设计亟待研究。本文采用脉冲Nd：YAG激光系统对Y₂O₃部分稳定ZrO₂（YSZ）热障涂层进行表面改性,研究了激光功率、扫描速度以及光束长度对改性层厚度、微观结构的影响。结果表明,激光改性层呈致密的柱状晶结构,并有纵向裂纹贯穿其中。改性层的厚度与激光功率成正比,受扫描速度影响不大,与光束长度成反比。激光功率过高,则改性层裂纹增加明显;光束长度过大,则改性层与下方涂层的界面缺陷增多,不利于界面结合。优化的激光改性参数为：激光的功率为75~80 W,扫描速度8 mm/s,光束长度为160 mm。设计了双层激光改性层,每层中的纵向裂纹不连续,使得整个改性层中无贯穿的纵向裂纹,有助于抑制高温腐蚀熔体的内渗。     

Effect of cooling strategies on performance and mechanism of helical milling of CFRP/Ti-6Al-4V stacks

Hole-making for Carbon Fiber Reinforced Plastics(CFRP)/Ti-6Al-4V stacks is crucial for the assembling strength of aircraft structure parts. This work carried out experimental work for helical milling(HM) of the stacks with sustainable cooling/lubrication(dry, MQL and cryogenic)conditions. Cutting forces and temperatures at the CFRP layer, Ti-6Al-4V layer and the interface of stacks were obtained by a developed measuring system. The temperatures in CFRP machining at cryogenic condition varied fro...     

TiB2颗粒诱导AlSi5电弧增材微观组织演变及性能研究

铝合金的电弧增材制造过程中因持续热积累而引起组织分布不均匀和溶质偏析,导致其性能各向异性。针对这一问题,设计了TiB₂纳米颗粒添加铝合金的钨极氩弧(Tungsten inert gas,TIG)增材制造工艺。在电弧增材制造过程中,通过表面预涂层的方式将纳米TiB₂颗粒添加到试样中,对比研究了纳米TiB₂颗粒不同质量分数对AlSi5合金微观组织的影响。结果表明,随着TiB₂质量分数的增加,AlSi5合金的微观组织不均匀性得到明显改善,1.5%TiB₂的添加使AlSi5合金的晶粒尺寸从226μm减小到85.6μm,且引起(110)和(112)基面上的织构明显减弱,最大取向密度呈下降的趋势;与无颗粒添加的AlSi5增材试样相比,颗粒添加后的沉积层硬度与弹性模量均得到显著提高,硬度值从879MPa增加到1253MPa,弹性模量从81.9GPa增加到88.3GPa。     

激光熔覆裂纹的形成机理及控制方法

激光熔覆技术是利用激光辐射使熔覆材料和基体表面同时熔化并快速凝固、从而显著改善基体材料物理性能的一种新工艺方法。但激光熔覆工艺的选择不当则会使熔覆层产生裂纹、气孔、未熔合等,从而影响熔覆制件的综合性能。本文研究了激光熔覆裂纹的种类以及熔覆层的应力类型,分析了裂纹产生的机理,指出材料间热膨胀系数、弹性模量的明显差别及激光熔池区域的温度梯度所决定的热应力是熔覆层裂纹形成的根源。并从熔覆材料和基体材料的合理选择、成形工艺参数的合理设计及热处理等方面,阐述了熔覆裂纹的影响因素和控制方法。