EROSION WEAR OF AlSi-GRAPHITE AND Ni/GRAPHITE ABRADABLE SEAL COATINGS

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ABRADABILITY EVALUATION AND TRIBOLOGICAL BEHAVIOUR OF ABRADABLE SEAL COATING

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EVALUATION OF Al-Si/POLYESTER ABRADABLE SEAL COATING

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Preparation and property of seal coating for gas turbine compressor

Double-layer structure of seal coating which consisted of a Ni5Al bond coating and a Ni25 graphite top coating were prepared on steel substrate of gas turbine compressor cylinder block.Bond coating was prepared by atmospheric plasma spraying and top coating was prepared by flame spraying.The microstructure,mechanical properties and abradability of the coating were characterized by scanning elec-tron microscope(SEM),hardness tester,universal testing machine,thermal shock testing machine and abradability testing machine.The res-ults show that the overall spraying structure of the seal coating is uniform,the nickel metal phase is the skeleton supporting the entire coat-ing,and the coating is well bonded without separation.The seal coating has a bonding strength of not less than 7.7 MPa,excellent thermal stability,and thermal shock resistance cycle numbers at 500℃more than 50;the scratch length,deepest invasion depth and wear amount of the coating increase with rise of test temperature,with almost no coating adhesion,indicating that the seal coating has excellent abradability.

Erosion wear behaviour and mechanism of abradable seal coating

The erosion wear behaviour and mechanism of several middle temperature seal coatings were investigated by a CMS 100 self made vacuum sand erosion machine. The results show that the relationship between the erosion mass loss and the erosion time is linear, the coatings hold a maximum erosion rate at 60° impact angle, and the relationship between the erosion rate and the impact speed is an exponential function. The speed exponent increases with the increase of the impact angle. At 90° impact, indentations and extruded lips were generated on the coating surface subjected to impact. With repetitive impact by the abrasive particles, the extruded lips were work hardened and peeled off, while flattened metal phase grains were impacted repeatedly, loosed and debonded. At 30° impact, the erosion wear of the coating is characterized by micro cutting, plowing and tunneling via pores and non metal phase. The model of the erosion mechanism is advanced on the basis of the above mentioned erosion wear behaviour.

隔热可磨耗封严涂层界面断裂行为的数值模拟

为探究隔热可磨耗封严涂层的失效行为,研究了界面粗糙度、界面附近可磨耗面层结构对复合涂层开裂的影响规律。采用内聚力模型以及相场法描述裂纹沿界面整体剥落以及可磨耗面层内部断裂行为,揭示了涂层的剥落失效机理。研究发现,随着界面粗糙度的增加,涂层结合强度和开裂趋势呈现相反的变化规律。一方面,无损伤复合涂层界面有效接触面积增大,结合强度提高;另一方面,随着粗糙度的增加,面层内部断裂更加容易。因此,需合理优化界面粗糙度。此外,界面附近面层孔隙会降低界面处的结合强度。据此,选择合适的界面粗糙度,并在可磨耗面层与隔热层之间引入抗开裂致密过渡层,以消除面层孔隙对复合涂层界面强度的弱化作用,设计出抗开裂涂层。

玻璃微珠填充硅树脂可磨耗层的制备工艺及其在航空发动机静子组合件上的应用

树脂基可磨耗层是航空发动机静子组合件的重要组成部件,利用其可磨耗性可保护转动件与静子组合件,并通过减小转动件与静子组合件之间的间隙优化航空发动机性能。采用加成型硅树脂为基体,研究不同粒径与堆积密度的实心/空心玻璃微珠对复合磨耗层加工性能的影响规律;采用专用磨耗试验机模拟高速叶片磨耗工况,研究不同种类与含量玻璃微珠对硅树脂复合材料磨耗性能的影响规律。结果表明:H型(粒径分布20~80 um)空心玻璃微珠填充硅树脂复合材料具有优异的表面质量、流淌性与综合性能。通过玻璃微珠填充填料优选与含量调控,结合工装设计以及灌注工艺参数调控,形成玻璃微珠填充硅树脂可磨耗层的可控制备工艺,并在航空发动机静子组合件上得到应用与验证。

镍石墨涂层酸性盐雾腐蚀后的组织结构与性能转变

采用热喷涂制备镍石墨(Ni-C)可磨耗封严涂层,并进行酸性盐雾192 h腐蚀。对酸性盐雾腐蚀前后涂层的组织结构、硬度、结合强度与可磨耗性能评价。结果表明:酸性盐雾腐蚀192 h后Ni-C涂层表面形成厚度约为200~300μm腐蚀区域,平均硬度由(34.4±3.2)HR15Y提升至(41.1±2.4)HR15Y,平均结合强度由(14.6±0.7)MPa下降到(13.3±0.6)MPa。这主要是由于酸性盐雾腐蚀过程中腐蚀区域内石墨等软质材料出现流失,导致了涂层的表面硬度出现增高趋势。同时,涂层腐蚀区域与下部未腐蚀区域的结合性较差,造成结合强度出现降低,且在可磨耗刮削过程中硬化的腐蚀层易发生剥落,避免对偶叶片因涂层硬度升高而磨损加剧。涂层的整体磨损机制并未发生明显转变,仍为塑性变形与黏着态磨损的混合磨损机制。

超长时间热处理后镍-石墨封严涂层力学性能演变特性分析

预测超长服役时间后镍-石墨封严涂层的可靠性对合理维护涂层和提升航空发动机工作效率具有重要意义。首先采用热喷涂技术制备了镍-石墨涂层样品,研究了在200℃、300℃和400℃下分别热处理400 h、800 h、1 200 h、1 600 h、2 000 h后镍-石墨涂层的微观结构及力学性能演变。研究表明:热处理时间及温度对涂层的性能有很大的影响。随着热处理时间的延长,涂层的硬度呈现先增大后减小的趋势。在400℃热处理2 000 h后,涂层的表面和截面硬度达到最小值,分别为0.46 GPa和0.63 GPa。涂层的内聚强度随热处理时间的延长先降低后略有增加再降低,400℃下热处理2 000 h后达到最小值0.43 MPa。镍和石墨发生氧化、晶粒生长、残余应力释放是导致在热处理过程中镍-石墨涂层力学性能发生变化的主要原因。

陶瓷基复合材料可磨耗环境障涂层制备及性能

随着碳化硅陶瓷基复材制备的涡轮外环的逐步应用,与其匹配的可磨耗涂层技术需求迫切。本工作采用大气等离子喷涂技术,制备4层结构的BSAS(Ba_(0.75)Sr_(0.25)Al_2Si_2O_8)-聚酯基可磨耗环境障涂层(A/EBCs),探究工艺参数对可磨耗面层孔隙率的影响规律以及涂层在1300℃下的相结构和组织演变。利用X射线衍射仪(XRD)、扫描电子显微镜(SEM)、能谱仪(EDS)、透射电镜(TEM)对涂层相结构、微观组织及成分进行分析表征。结果表明:BSAS-聚酯基可磨耗面层的孔隙率为26.4%~36.8%,BSAS-聚酯粒子温度敏感的参量是主气(氩气)流量、辅气(氢气)流量和喷涂距离,速度敏感的参量是主气(氩气)流量;其中主气(氩气)流量同时对BSAS-聚酯的粒子温度和速度具有反向影响作用。该可磨耗面层在1300℃高温氧化300 h保持单斜相结构,组织和成分稳定,局部析出球状非晶氧化硅颗粒。采用高温高速刮削实验对涂层可磨耗性能进行评价,涂层表面发现纳米高温合金微粒黏附,叶片高度磨损比(IDR)为20%,达到可磨耗封严涂层使用要求。

酸性盐雾腐蚀后镍硅氮化硼涂层的可磨耗性能转变研究

采用大气等离子喷涂制备镍硅氮化硼(NiSi-BN)可磨耗封严涂层并进行酸性盐雾192 h腐蚀处理。对腐蚀前后涂层的组织结构、硬度、结合强度进行分析。采用高温超高速可磨耗试验机研究腐蚀前后的涂层在650℃下与GH4169叶片的可磨耗刮削行为的差异性。研究结果表明:酸性盐雾腐蚀后NiSi-BN涂层的平均硬度由(11.9±0.40)HBW升高为(18.2±1.7)HBW,平均结合强度为变化不大,为(6.7±1.5)MPa,IDR值由腐蚀前10.77%±0.74%升高至26.70%±4.60%,酸性盐雾腐蚀192 h后NiSi-BN涂层的可磨耗性能出现明显下降。这主要是由于腐蚀区域涂层的硬度较高,造成叶片的磨损高度由腐蚀前的(0.05±0.01)mm增加至腐蚀后的(0.12±0.03)mm,对偶叶片与涂层间的摩擦作用更为剧烈,进而腐蚀态涂层的IDR值出现升高,涂层的可磨耗性能降低。

NiCrFeAl-BN涂层和NiCrFeAl-B.e涂层对磨TC11合金可磨耗性能研究

采用等离子制备NiCoCrAlY底层和YSZ中间层,火焰喷涂制备镍基氮化硼(NiCrFeAl-BN)和镍基膨润土(NiCrFeAl-B.e)面层可磨耗封严涂层。在高温超高速可磨耗试验机上进行涂层与TC11模拟叶片对磨,设置室温和600℃,不同进给速率条件,对两种涂层进行可磨耗性能评价。结果表明:进给速率对两种涂层刮削后微观形貌影响较大,但对封严层厚度影响较小。温度提高,对两种涂层破坏作用都有所增加,可磨耗性能下降。相同工况下NiCrFeAl-BN涂层的可磨耗性均优于NiCrFeAl-B.e涂层,但对磨后的叶片高度磨损比值(IDR)仍较大,在叶片叶尖电镀BN涂层后,进给速率为5μm s时,IDR由16.05%变为8.04%,起到一定保护叶片的作用。

hBN含量对CuAl/hBN封严涂层高温磨损性能的影响

目的 研究hBN含量对CuAl/hBN可磨耗封严涂层在450℃下磨耗性能的影响。方法 利用大气等离子喷涂工艺制备原始粉末中hBN质量分数分别为10%、15%、20%、25%的Cu Al/hBN涂层。采用QUALITEST表面洛式硬度仪表征喷涂态涂层表面洛氏硬度。采用高温摩擦磨损试验机及场发射扫描电镜等方法,表征450℃下涂层及摩擦副的磨损形貌和质量磨损比,探讨涂层的磨损机理。结果 随着原始粉末中hBN质量分数由10%增加至25%,所制备喷涂态涂层的表面洛式硬度逐渐降低,分别为69HR15Y、56HR15Y、46HR15Y、36HR15Y。涂层与摩擦副之间的质量磨损比分别为-0.88%、-0.25%、-0.13%、-1.40%,在原始粉末中hBN质量分数为20%时质量磨损比更接近0,涂层磨耗性能更优异。涂层与摩擦副在相对摩擦过程中,主要以涂层的磨损剥落为主。在摩擦销接触面上同时观察到混合转移层,且随着涂层hBN含量的增高,接触面转移层质量先减小后增大,表面涂抹程度更加平缓,形貌起伏更加均匀。结论 低线速度条件下,摩擦热效应对涂层及摩擦副形貌及二者间的磨损行为的影响起关键作用。hBN组分理论上存在最优值,保证封严涂层获得最佳的磨耗性能。综合而言,CuAl/20%hBN涂层与摩擦副的摩擦相容性更优异。

抗剥落金属基可磨耗封严涂层结构匹配制备研究

新一代航空发动机对推重比提出更高的要求,而发动机叶尖与机匣的间隙是影响发动机效率的关键因素之一。在机匣内壁制备可磨耗封严涂层能有效减小气流泄漏、避免叶尖与机匣碰磨,从而使发动机高效、安全地运行。可磨耗封严涂层通常具有高孔隙率,然而高孔隙率易降低可磨耗面层/陶瓷隔热层界面强度,引发可磨耗涂层整体剥落。为此,开展可磨耗封严面层/陶瓷隔热层界面结构匹配设计,在保证涂层可磨耗封严功能的基础上,增强二者界面抗剥落能力。首先,通过数值分析方法发现,可磨耗层/陶瓷层界面处孔隙特征尺寸和孔隙率增加均会加剧可磨耗层沿界面剥落的风险。进一步,提出可磨耗封严涂层的结构匹配设计,即在靠近界面处增加抗剥落过渡层。最后,通过模拟和试验相结合,优化抗剥落过渡层厚度,证实过渡层可显著延长体系的服役寿命。

铝基可磨耗封严涂层制备及性能评价研究进展

随着航空航天技术的发展,人们对发动机效率的要求越来越高。减小涡轮机叶片尖端与机匣之间的缝隙,有利于发动机效率的提升。叶片尖端与发动机涡轮机机匣之间喷涂可磨耗封严涂层,不仅可封严气路、提高发动机效率,又可以减少对叶片的磨损以保护叶片。对于可磨耗封严涂层而言,可磨耗性是其最重要、最本质的特性。综述了国内外铝基封严涂层的粉末制备、喷涂及可磨耗性能评价的研究现状,分析了粉体形式、喷涂参数对涂层组织的影响,以及涂层表面洛氏硬度、叶尖的进给速率/单道进给量、摩擦线速度等对涂层的可磨耗性能的影响,同时还对海洋环境下铝基封严涂层的腐蚀机理进行研究,指出了机器学习、仿真技术在可磨耗涂层性能预测及性能表征等方面的作用。最后,总结了近年来铝基可磨耗封严涂层的研究进展,并对未来的研究方向进行了展望。

Homologous layered InFeO3(ZnO)m:new promising abradable seal coating materials

As promising abradable seal coating materials used in high temperature range, the homologous layered InFeO3（ZnO）m （m = 1, 2, 3...20） have attracted great attention. In this short review, we summary the research progress in InFeO3（ZnO）m that were developed in our group. We first introduced a series of conventional abradable seal coating materials as a research motivation. Second, the phase composition and crystal structures of lnFeO3（ZnO）m system were presented. Then, their thermophysical properties, as the most important part, were introduced in detail. At last, the mechanical properties such as hardness, friction coefficient, erosion wear resistance of InFeO3（ZnO）m system were also described. Our summary indicates that InFeO3（ZnO）m sys- tems are promising abradable seal coating materials.

Corrosion mechanism of CuAl-NiC abradable seal coating system——The influence of porosity,multiphase,and multilayer structure on the corrosion failure

In this study,the corrosion behavior of the CuAl-NiC abradable seal coating system in chloride solution was investigated to systematically research the effect of porosity,multiphase,and multilayer structure on the corrosion failure.Through the composition and structure analysis,the corrosion process of the system was predicted and then verified with mercury intrusion porosimetry,cross-section SEM/EDS analysis,and electrochemical measurements.The results demonstrated that the interphase selective corrosion caused the porosity of the top layer to decrease first and then increase during the corrosion development.The interlayer galvanic corrosion,determined by the pore connectivity,is crucial for corrosion failure.

铜铝聚苯酯封严涂层耐蚀性能和可磨耗性能研究

采用等离子喷涂工艺制备了铜铝聚苯酯封严涂层,完成了96 h中性盐雾试验、72 h酸性大气试验、24 d周期浸润试验以及450℃、线速度300 m/s、进给速率5~480μm/s的高温高速可磨耗试验,研究了涂层的耐蚀性能和可磨耗性能。结果表明:铜铝聚苯酯封严涂层在72h酸性大气腐蚀后,涂层表面光滑平整,未观察到腐蚀产物和点蚀坑;24 d周期的浸润腐蚀后,涂层颜色未发生明显改变,涂层表面结构完整,未观察到腐蚀产物和点蚀坑;96 h中性盐雾腐蚀后,涂层表面未观察到腐蚀坑,但涂层表面出现大片褐色斑块;不同进给速率下,叶片进给深度比IDR值不大于9.79%;检测及分析结果表明,涂层拥有优异的耐腐蚀性能和可磨耗性能。

High-Speed Rubbing Behavior of Abrasive Coating Coated on Titanium Alloy Blade Tips

In aero-engines, abrasive coatings are typically utilized to protect the blade tip from excessive wear caused by the harder abradable sealing coating and thereby improve the sealing performance of engines. Therefore, a Ni/cBN abrasive coating was prepared on titanium alloy using electrodeposition. The high-speed rubbing tests with a linear velocity of 350 m/s and different incursion rates were performed to investigate the effect of the Ni/cBN abrasive coating on the wear behavior against NiCrAl/diatomite seal coating. Results showed that melting wear and adhesive transfer occurred on the bare blades, causing the bare blade to suffer excessive wear. While the Ni/cBN abrasive coating exhibited superior wear resistance and cutting performance. The cBN grits pullout, the abrasion of Ni matrix and transfer of seal coating to the cBN grits were the main wear mechanism of the Ni/cBN abrasive coating. Additionally, it was found that the relationship between the incursion rate and high-speed rubbing behavior is quite different for the bare blade and Ni/cBN coating. The reason for the difference in wear behavior of bare blade and Ni/cBN coating at different incursion rates was discussed in detail.

SiC_(f)/SiC复材表面Sc_(2)O_(3)-Y_(2)O_(3)-ZrO_(2)基梯度可磨耗涂层设计及性能研究

SiC_(f)/SiC陶瓷基复合材料是未来航空发动机重要材料之一,其表面涂层是保护SiC_(f)/SiC陶瓷基复合材料关键技术。针对陶瓷基复材表面的Sc_(2)O_(3)-Y_(2)O_(3)-ZrO_(2)基可磨耗涂层与EBC涂层结合力不够高、应力匹配性差等问题,开展Sc_(2)O_(3)-Y_(2)O_(3)-ZrO_(2)基梯度可磨耗涂层设计、制备与考核技术研究,并且与非梯度可磨耗涂层进行性能对比。研究结果表明:梯度可磨耗涂层比非梯度可磨耗涂层结合强度提高了6.7%;在(1250±50)℃高温冲击1000次后,梯度可磨耗涂层剥落面积仅为非梯度可磨耗涂层剥落面积的1/6。因此,梯度可磨耗涂层具有更好的力学性能,有望在未来航空发动机中得到广泛应用。