Yuan等[17~20]研究了不同热暴露时间、温度及热力耦合后涂层体系的组织演变。结果表明:Al元素的向内扩散和Ni元素的向外流失使共格排列的γ/γ'相结构遭到破坏并促进TCP相的生成,降低了合金的高温力学性能。为了模拟涡轮叶片的服役工况,预先对含涂层试样进行热暴露然后开展蠕变试验。Alam等[11,21,22]发现,随着热暴露时间的延长涂层体系发生退化,裂纹在界面萌生并沿γ'/β相界、孔洞等缺陷“双向扩展”,使合金的蠕变性能降低。Han等[23,24]针探究了含渗铝涂层的K403镍基高温合金涡轮叶片的服役损伤机理,发现涂层在高温下长时服役过程中发生组织退化、产生表面损伤和孔洞。多种损伤的积累加速涂层的剥落,恶化了体系的服役表现。但是,目前针对长时服役后Pt-Al涂层/单晶高温合金体系的研究,较多的是围绕基体组织退化、涂层退化和性能恶化,关于服役温度对涂层/基体界面演化的影响的研究还比较少[25~27]。鉴于此,本文研究在不同温度(850℃、1000℃)下抗热腐蚀单晶高温合金/Pt-Al涂层体系的长时服役行为,以及界面及界面附近的微观组织演化规律,以深入了解微观结构演变与互扩散反应之间的关联。
1 实验方法
1.1 实验用材料
实验用抗热腐蚀镍基单晶高温合金DD413的名义成分,列于表1。用真空感应炉熔炼母合金,用传统高速凝固Bridgman法(High Rate Solidification,HRS)制备单晶试棒。用电子背散射衍射技术(Electron Backscattered Diffraction,EBSD)确定单晶试棒的晶体取向,其晶体取向与<001>生长方向的取向差均小于10°。
表1 DD413合金名义成分(%,质量分数)
Table 1
| Alloy | C | Cr | Co | W | Mo | Al | Ti | Ta | Ni |
|---|---|---|---|---|---|---|---|---|---|
| DD413 | 0.07 | 12 | 9 | 3.8 | 1.9 | 3.6 | 4.1 | 5 | Bal. |
按照1220℃/2 h+1250℃/4 h(Air cooling;AC)+1080℃/4 h(AC) 的制度进行热处理,然后用电火花线切割机沿<001>方向将试棒切成直径为14 mm、厚度为2 mm的试片(试片表面的法线为<001>生长方向)。将试片进行倒角(R=1)处理后,用800#砂纸进行磨抛。
1.2 涂层的制备
将试片吹砂和清洗后用电镀法在试片表面沉积一层厚度约为4 μm的Pt层,然后放入VGQ-80型真空炉进行1080℃/4 h的退火处理。退火处理后,用高温低活度渗铝工艺进行渗铝,渗铝剂为Fe-Al粉和活化剂NH4Cl的混合粉末。将炉腔抽成真空状态后充入氩气,反复几次确保将炉腔内的空气排尽后即可加热,渗铝结束后试样随炉自然冷却至室温。
1.3 长期热暴露实验
将试片装入坩埚并置于马弗炉中,分别在 850℃、1000℃进行长期热暴露实验,热暴露时间分别为50 h、100 h、300 h、600 h、1800 h、3600 h。在每个时间段各取3个样品用于观察显微组织。
1.4 微观组织表征
用X'Pert PRO型X射线衍射仪(XRD)进行分析涂层的物相。用配有能谱仪(EDS)和背散射电子(BSE)的Tescan MIRA 3型扫描电镜(SEM),观察金相样品的微观形貌、组织和成分(腐蚀液为4 g CuSO4+12 mL HCl+20 mL H2O)。
用FEI T20型透射电镜并使用选区衍射技术(SAD)鉴定互扩散区及二次反应区中的物相。透射样品的制备:沿<001>方向切取厚度约为500 μm的薄片样品(如图1所示),依次将基体面和涂层面研磨(为避免研磨导致涂层脱落,仅针对涂层面采用细砂纸进行简单研磨)至约50 μm(使互扩散区/二次反应区位于样品的中间层),然后将样品冲成直径为3 mm的圆片。用Tenupol-5电解双喷减薄仪对样品进行减薄,以此获得易于观察的薄区。(双喷的参数为:电压20 V,双喷液为10%高氯酸+90%酒精溶液,温度为-20℃~-25℃,冷却介质为液氮)。
图1
1.5 图像分析
使用Image Pro Plus图像分析软件测量互扩散区、二次反应区的厚度。为确保数据的准确性,选取3张视场大小相同SEM图像进行厚度测量,且测量点不少于50个。统计互扩散区中的高亮粒子的尺寸及体积分数,视场大小相同且每张图像中的粒子数量不少于200个。因为析出相多为不规则图形,借助等效直径
衡量不规则形状析出相的演变规律[28]。式中Req为粒子等效直径(Equivalent diameter),S为粒子面积。
2 结果和讨论
2.1 Pt-Al涂层原始截面的形貌
图2给出了热暴露前DD413合金表面Pt-Al涂层的XRD谱。由图2可见,涂层由单相β-(Ni,Pt)Al相组成。图3a给出了DD413合金/Pt-Al涂层的截面形貌,可见涂层分为两个区域:外层(Outer coating,OC)由单一β相构成,厚度为(20±1 μm);内层为互扩散区(Interdiffusion of zone,IDZ),以β-(Ni,Pt)Al相为基,弥散分布着析出相(富Cr、Ta、W、Mo等),厚度为(14±0.5 μm),主要受互扩散反应的影响,在涂层/基体间生成的一个连续区域[29](如图3a所标注)。图3b给出了涂层区域红色方框的EDS定量分析结果:涂层的成分为Ni-35.3Pt-16.1Al-4.6Cr-4.2Co(质量分数,%)。
图2
图3
图3
原始态Pt-Al涂层/合金截面的形貌和形貌中红色方框对应EDS能谱
Fig.3
(a) Cross section morphology of original Pt-Al coating/Alloy and (b) EDS energy spectrum corresponding to red box in (a)
图4a给出了DD413合金/Pt-Al涂层蚀刻后的BSE图。受蚀刻的影响,涂层组织中出现些许裂纹。可以看出,在IDZ区下方出现零散分布的基体扩散区(Substrate diffusion zone,SDZ)(图4a虚线所示)。此外,靠近互扩散区的基体γ'相发生了筏化(筏化方向平行于试样表面),其厚度为5±0.8 μm,如图4b所示。γ'形筏主要是预先的喷砂处理和后续的涂层热加所致[29]。远离涂层基体内部的γ'相为正方体结构,如图4c所示。互扩散区中有两种不同衬度的相析出,细节如图4a中的插图所示;具体成分如图4d、e所示,较亮的析出相为富Ta和Ti的MC碳化物,另一种较暗的相为富Cr相。SAD分析结果(图5)表明,富Cr相为σ-TCP相。使用图像分析软件统计和计算了互扩散区中MC碳化物的尺寸和体积分数(σ-TCP相与基体衬度差异较小,因此没有统计),结果表明:MC碳化物的平均尺寸为(0.13±0.006) μm,体积分数为(7.3±0.7)%。
图4
图4
Pt-Al涂层/合金截面蚀刻后的BSE图像和EDS能谱
Fig.4
BSE images and EDS spectrum of Pt-Al coating/alloy section after etched: (a) sectional image of Pt-Al coating; (b, c) enlarged image of coating/substrate interface image of γ/γ'; (d, e) are the corresponding MC and σ-TCP EDS spectra in (a)
图5
图5
Pt-Al涂层/合金的TEM图像及选区衍射花样(SAD)
Fig.5
TEM image and selected area diffraction pattern (SAD) of Pt-Al coating/alloy (a) TEM image of interdiffusion region of original coating; (A) and (B) selected area diffraction (SAD) corresponding to (a)
2.2 涂层/基体界面微观组织的演化
涂层-基体间的化学组分明显不同,在长时热暴露过程中持续进行的互扩散,诱发了界面附近微观组织的演化。随着热暴露时间的延长和热暴露温度的提高,涂层/基体界面微观结构的演化愈加剧烈。在此,分析几个关键组织损伤参量(IDZ、SRZ (Secondary reaction of zone,SRZ)),用厚度和富集难熔元素析出相的尺寸、体积分数量化表征界面微观组织的演化规律。
2.3 在850℃热暴露界面微观组织的演化
图6a给出了在850℃热暴露50 h后DD413合金/Pt-Al涂层的截面BSE图像。与原始态组织(图3a)比较,热暴露50 h后互扩散区内MC碳化物的尺寸略微增大(约为0.17 μm),其体积分数由7.3%增大到8.7%;温度和互扩散等因素的影响使σ-TCP相也发生了不同程度的溶解或长大。由于其与基体相衬度差异较小,无法量化表征其演化规律。受涂层/基体互扩散反应的影响,也观察到SRZ,其形成在互扩散区下方,由γ相、γ'相、TCP相及三相转换产物所形成的区域[30],如图8所示。此时,IDZ、SRZ分别增大到17.7 μm和11.1 μm。同时,MC相的体积分数和尺寸变化可能受到喷砂产生的表面再结晶的影响——晶界和位错为(Ta、Ti)元素的扩散提供了通道[31],涂层/基体间的化学势梯度也使互扩散区中MC碳化物的长大。
图6
图6
在850℃热暴露不同时间后Pt-Al涂层/合金截面的BSE图像
Fig.6
BSE images of Pt-Al coating/alloy section after long-term thermal exposure at 850℃ for different time (a) 50 h; (b)600 h; (c) 1800 h; (d) 3600 h
图7
图7
850℃热暴露3600 h后IDZ中的块状析出相的TEM图像及选区衍射花样(SAD)
Fig.7
TEM image and selected area diffraction patterns (SAD) of block precipitated in IDZ after heat exposure at 850℃ for 3600 h
图8
图8
在850℃热暴露不同时间后蚀刻的Pt-Al涂层/合金截面的BSE图像
Fig.8
BSE images of Pt Al coating/alloy section etched after thermal exposure at 850℃ for different time (a) 50 h; (b) 600 h; (c) 1800 h; (d) 3600 h
图9
图9
在850℃热暴露3600 h后的TEM图像、选区衍射花样(SAD)和针状相对应的EDS能谱
Fig.9
(a) TEM image after thermal exposure at 850℃ for 3600 h and selected area diffraction pattern (SAD), (b) EDS energy spectrum corresponding to needle phase in (a)
图10
图10
在1000℃长时热暴露不同时间后Pt-Al涂层/合金截面的BSE图像:
Fig.10
BSE images of Pt-Al coating/alloy section after long-term thermal exposure at 1000℃ for different time (a) 50 h; (b)600 h; (c)1800 h; (d) 3600 h
图11
图11
在850℃和1000℃热暴露后IDZ、SRZ厚度的演化趋势
Fig.11
Evolution trend of thickness of IDZ (a) and SRZ (b) after 850℃ and 1000℃ thermal exposure
图12
图12
在850℃和1000℃热暴露后IDZ中MC碳化物的演化趋势
Fig.12
Evolution trend of MC carbide in IDZ after thermal exposure at 850℃ and 1000℃ (a) Average size of MC carbide; (b) Volume fraction of MC carbide
图13
图13
长期热暴露后Pt-Al/DD413体系的XRD谱
Fig.13
XRD pattern of Pt-Al / DD413 system after long-term thermal exposure (a) 850℃/0-3600 h; (b) 1000℃/0-3600 h
同时,在长时热暴露过程中难熔元素出现局部过饱和,针状相在界面下方析出。图9给出了针状TCP相的TEM图像、选区衍射花样(SAD)和EDS能谱,分析结果表明针状相为σ相。对比分析发现,随着热暴露时间的延长σ析出相的含量明显提高。
2.4 在1000℃热暴露界面微观组织的演化
如图10c所示,当热暴露时间持续到1800h时 MC碳化物只占1.2%(此时,MC碳化物几乎全部溶解在互扩散区中,存在较大的计算误差。所以,在此之后没有给出与MC碳化物尺寸相关的数据)。除了C碳化物,在互扩散区中还发现尺寸较大的TCP相和M23C6碳化物(分别在图10c中标出);IDZ和SRZ的厚度分别为23.5 μm和49.3 μm。图10d给出了在1000℃热暴露3600 h后DD413合金/Pt-Al涂层的截面BSE图像。可以看出,β→γ/γ'相变产生的体积收缩使涂层表面出现起伏,Al损耗比在850℃热暴露更加严重;此时的互扩散区以γ/γ'为基,弥散分布着MC、M23C6碳化物和σ-TCP。IDZ和SRZ的厚度分别为23.1 μm和62.3 μm。
与在850℃热暴露相比,在1000℃热暴露时合金/涂层界面微观组织的演化更快。在1000℃长时热暴露使互扩散区的厚度和二次反应的厚度都比在850℃热暴露时大。对比分析发现,MC碳化物的溶解和M23C6的析出明显加速;同时,在1000℃热暴露时TCP相的尺寸也比在850℃热暴露时略大,如图11、12所示。出现以上现象的原因是:一方面,β-(Ni,Pt)Al向γ/γ'相的转变加速,如图13b所示。互扩散区中Ta、Ti元素被γ'相吸收[35]使MC碳化物溶解。同时,σ-TCP相在高温下不稳定而易发生分解,闲置下来的Cr与C结合也加快了M23C6的形成[36],如图10b所示。另一方面,高温使大量的Al元素扩散进入基体,Ni元素向外流失使反应
更加剧烈。这使更多的γ'相在界面下方生成,而γ相中元素的扩散速率比γ'相的扩散速率高1-2数量级[37],因此γ'相限制了元素的向外扩散。同时,γ'相比Cr、Co、Mo、W等难熔元素的溶解性较差,使更多的难熔元素在界面偏聚并以针状相的形式在界面下方析出。文献[38]指出,针状TCP相限制了基体中元素向外扩散,减少了难熔元素在互扩散区中的聚集。虽然γ'相和TCP相在一定程度上限制了基体元素向外流失,但是与Ta、Ti等元素相比,来自基体深处的Ni更容易向外补充[10]。Ni元素不断向外扩散,使难熔元素在互扩散区中的局部溶解能力提高。因此,在1000℃长期热暴露过程中,涂层相变和涂层/基体的互扩散加速了互扩散区中MC碳化物的溶解和M23C6碳化物的析出。
与在850℃热暴露相比,在1000℃长时热暴露后涂层和界面的损伤随着热暴露时间的延长愈加严重。图14a~d分别给出了蚀刻后在1000℃热暴露50 h、600 h、1800 h、3600 h后Pt-Al涂层的截面图像和界面γ/γ'相的放大图像。可以看出,界面下方的γ'相互相联接形成筏化结构,但是仍存在部分独立的立方状γ'相。随着热暴露时间的延长筏化层不断深入,如图14a~d中的插图所示。大量的难熔元素释放出来生成了TCP相,SAD分析结果表明针状相为σ-TCP,如图15所示。另外,在高温下随着热暴露时间的延长氧化反应和互扩散反应持续进行,使Al元素的损耗加剧和发生β-(Ni,Pt)Al→γ'→γ转变。随着界面组织中γ相体积分数的增大γ'相形成元素Ta和Ti则处于游离状态,加之C较快的扩散使其与Ta、Ti重新结合并以二次MC的形式在界面组织中析出,如图15b~d界面组织中的高亮相。
图14
图14
Pt-Al涂层/合金截面蚀刻后在1000℃长时热暴露不同时间后的BSE图像
Fig.14
BSE images of Pt-Al coating/alloy section after long-term thermal exposure at 1000℃ for different time (a) 50 h; (b)600 h; (c) 1800 h; (d) 3600 h
图15
图15
在1000℃/3600 h后的TEM形貌、选区衍射花样(SAD)和与针状相对应的EDS能谱
Fig.15
(a) 1000℃/3600 h, TEM image and selected area diffraction pattern (SAD) and (b) EDS energy spectrum corresponding to needle phase in (a)
在不同温度下近涂层γ/γ'相也发生了不同程度的退化,其原因是:(1)在高温下合金基体(FCC)的热膨胀系数略大于β-(Ni,Pt)Al涂层(BCC),喷砂处理使界面应变能无法释放,涂层相对基体产生了平行于界面的压应力[32],使界面下方的γ'相形筏。(2) 在1000℃热暴露时涂层中的Al与O2的剧烈反应支撑了表面氧化层的生成,与在850℃热暴露相比,由β到γ/γ'的转变明显加速,如图13所示。而β相的晶粒尺寸略大于γ'相,在热暴露过程中伴随相变反应的进行涂层的体积收缩,出现在涂层中的应力使界面γ'相筏化层不断深入[39]。(3)涂层/基体互扩散反应:高温下,剧烈的反应(3、4)使界面附近γ'相的体积分数增大,影响γ/γ'相的错配度[38],进一步使界面下方的γ'相形筏出现差异。
综上所述,在不同温度下长期热暴露后界面下方发生γ'相筏化的原因,是涂层相变和涂层/基体间持续进行的互扩散反应。
3 结论
(1) DD413合金/Pt-Al涂层在不同温度下热暴露的前期,MC碳化物的体积分数和尺寸发生不同程度的增大,随着热暴露时间的延长MC碳化物和σ-TCP相在互扩散区内逐渐溶解;热暴露3600 h后少量MC碳化物和部分σ-TCP相分布在互扩散区中,并有M23C6在界面组织中析出。随着热暴露温度的提高界面组织的退化严重,使以上进程明显加速。
(2) 长时热暴露后SRZ出现在界面下方,热暴露温度为1000℃时SRZ的厚度和σ-TCP相的尺寸均比在850℃热暴露时大。
(3) 长时热暴露后近涂层基体立方状γ'相依次发生球化和相互联接成筏形转变。随着热暴露温度提高到1000℃近涂层基体γ'相的损伤愈加严重,界面下方的部分γ'已形筏(平行于试样表面),且随着热暴露时间的延长筏化层厚度不断增大,并向基体内部延伸。
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Effect of surface roughness on corrosion behavior of the superalloy IN718 in simulated marine environment
[J].
Oxidation protection of enamel coated Ni based superalloys: Microstructure and interfacial reaction
[J].
Influence of high-temperature protective coatings on the mechanical properties of nickel-based superalloys
[J].
Improving cyclic oxidation resistance of Ni3Al-based single crystal superalloy with low-diffusion platinum-modified aluminide coating
[J].A low-diffusion NiRePtAl coating ((Ni,Pt)Al outer layer in addition to a Re-rich diffusion barrier layer) was prepared on a Ni3Al-base single crystal (SC) superalloy via electroplating and gaseous aluminizing treatments, wherein the electroplating procedures consisted of the composite deposition of Ni-Re followed by electroplating of Pt. In order to perform a comparison with conventional NiAl and (Ni,Pt)Al coatings, the cyclic oxidation performance of the NiRePtAl coating was evaluated at 1100 and 1150 °C. We observed that the oxidation resistance of the NiRePtAl coating was significantly improved by the greater presence of the residual β-NiAl phase in the outer layer and the lesser outward-diffusion of Mo from the substrate. In addition, the coating with the Re-rich diffusion barrier demonstrated a lower extent of interdiffusion into the substrate, where the thickness of the second reaction zone (SRZ) in the substrate alloy decreased by 25 %. The mechanisms responsible for improving the oxidation resistance and decreasing the extent of SRZ formation are discussed, in which a particular attention is paid to the inhibition of the outward diffusion of Mo by the Re-based diffusion barrier.
Influence of thermal exposure on the creep properties of an aluminized Ni-based single crystal superalloy in different surface orientations
[J].
Long-term thermal exposure responses of the microstructure and properties of a cast Ni-base superalloy
[J].
Microstructure and composition evolution of a single-crystal superalloy caused by elements interdiffusion with an overlay NiCrAlY coating on oxidation
[J].MCrAlY (M=Ni and/or Co) overlay coating is widely used as a protective coating against high temperature oxidation and corrosion. However, due to its big difference in chemical composition with the underlying superalloy, elements interdiffusion occurs inevitably. One of the direct results is the formation of interdiffusion zone (IDZ) and secondary reaction zone (SRZ) with a high density of fine topological closed-packed phases (TCPs), weakening dramatically the mechanical properties of the alloy substrate. It is by now the main problem of modern high-temperature metallic coatings, but there are still hardly any reports studying the formation, growth and transformation of IDZ and SRZ in deep, as well as the precipitation of TCPs. In this work, a typical NiCrAlY coating is deposited by arc ion plating on a single-crystal superalloy N5. Elements interdiffusion between them and its relationship on microstructure were clarified. Cr rather than Al from the coating diffuses into the alloy at high temperatures and segregates immediately beneath their interface, contributing largely to the formation of IDZ. Simultaneously, diffusion of Ni from the deep alloy to IDZ leads to the formation and continuous expansion of SRZ.
Creep behavior of Pt-aluminide (PtAl) coated directionally solidified Ni-based superalloy CM-247LC after thermal exposure
[J].
Coarsening kinetics of γ' precipitates in a Re-containing Ni-based single crystal superalloy during long-term aging
[J].
Growth kinetics of γ' precipitates in superalloy IN-738LC during long term aging
[J].
The effect of stress on primary MC carbides degeneration of Waspaloy during long term thermal exposure
[J].
Evolution of TCP phase during long term thermal exposure in several Re-Containing single crystal superalloys
[J].
The influence of high temperature annealing and creep on the microstructure and chemical element distribution in the γ, γ' and TCP phases in single crystal Ni-base superalloy
[J].
Modeling of microstructural evolution and lifetime prediction of MCrAlY coatings on nickel based superalloys during high temperature oxidation
[J].
Comprehensive study on the microstructure evolution and oxidation resistance performance of NiCoCrAlYTa coating during isothermal oxidation at High temperature
[J].
Microstructural and microchemical development of simple and Pt-modified aluminide diffusion coatings during long term oxidation at 1050℃
[J].
Influence of aluminide diffusion coating on the tensile properties of the Ni-base superalloy René 80
[J].
Effect of prior cyclic oxidation on the creep behavior of directionally solidified (DS) CM-247LC alloy
[J].
Oxidation-induced damage of an uncoated and coated nickel-based superalloy under simulated gas environment
[J].
Service damage mechanism and interface cracking behavior of Ni-based superalloy turbine blades with aluminized coating
[J].
Creep/fatigue accelerated failure of Ni-based superalloy turbine blade: Microscopic characteristics and void migration mechanism
[J].
Influences of MCrAlY coatings on oxidation resistance of single crystal superalloy DD98M and their inter-diffusion behaviors
[J].
Mechanism of the oxidation and degradation of the aluminide coating on the nickel-base single-crystal superalloy DD32M
[J].
Effect of substrate alloy composition on the oxidation behaviour and degradation of aluminide coatings on two Ni base superalloys
[J].
Creep life prediction of thermally exposed rene 80 superalloy
[J].
Effect of Ta on microstructural evolution of NiCrAlYSi coated Ni-base single crystal superalloys
[J].
A new type of microstructural instability in superalloys-SRZ
[J].
Effect of sand blasting and glass matrix composite coating on oxidation resistance of a nickel-based superalloy at 1000℃
[J].
Microstructure evolution and elemental diffusion behavior near the interface of Cr2AlC and single crystal superalloy DD5 at elevated temperatures
[J].
Coating-associated microstructure evolution and elemental interdiffusion behavior at a Mo-rich nickel-based superalloy
[J].
Formation of carbides and their effects on stress rupture of a Ni-base single crystal superalloy
[J].
Dissolution behavior of intragranular M23C6 carbide in 617B Ni-base superalloy during long-term aging
[J].
Microstructural evolution of NiCoCrAlY coated directionally solidified superalloy
[J].
Assessment of the diffusion mobilites in the γ' and B2 phases in the Ni-Al-Cr system
[J].
Secondary reaction zone formations in coated Ni-base single crystal superalloys
[J].
