The Effect of Linear Speed on the Wear Behavior of TC4 Blade and Ni-G Seal Coating
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摘要: 利用高速刮擦试验机模拟了压气机叶片与封严涂层的刮擦行为,研究了TC4(钛合金)叶片材料与Ni-G(镍-石墨)封严涂层体系在线速度30~150 m/s范围内的磨损行为.通过对叶片样品端面及涂层样品磨痕的SEM-EDS、XPS分析和涂层样品磨痕表面的显微硬度测试,探讨了对摩体系的磨损机制.结果表明:随着线速度的增大,叶片样品的磨损率呈现先升后降的趋势;在低线速度下涂层样品致密化使叶片样品磨损轻微,中等线速度下叶片样品与涂层样品磨痕中高硬度转移层的刮擦造成叶片样品磨损加剧,高线速度下叶片样品端面较厚氧化膜减轻叶片材料向涂层的转移导致叶片样品磨损下降.Abstract: The rubbing behavior between compressor's blade tip and seal coating was simulated through a high speed rubbing test rig. The wear behavior of TC4 (titanium alloy) blade and Ni-G (nickel-graphite) seal coating under linear speed varying from 30 m/s to 150 m/s was studied. The wear mechanism of the rubbing system was studied based on the results from scanning electron microscopy, energy dispersive spectroscopy and X-ray photoelectron spectrometer of the wear scar of the blade tip and the seal coating plus the vickers microhardness test of the coating's wear scar surface. The results reveal that with the increase of the linear speed, the wear rate of the blade firstly increased, then decreased. At low linear speed, thanks to the severe densification of the coating, the wear of the blade was mild. The rubbing between the blad and the coating wear scar's transfer layer of which the microhardness was high resulted in significant wear of the blade at medium speed. At high speed, the thick oxide layer on the blade tip prevented the transferring to the coating from the blade and the wear of the blade was mitigated.
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Keywords:
- high speed rubbing /
- wear mechanism /
- seal coating /
- linear speed
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[1] Chupp R E, R C Hendricks, S B Lattime, et al. Sealing in Turbomachine, 2006.
[2] Ludwig L P, R C Bill. Gas path sealing in turbine engines[J]. Asle Transactions, 1980, 23(1): 1-22.
[3] 刘夙伟, 李曙, 刘阳. 封严涂层材料及其可刮削性的评价[J]. 中国表面工程, 2009, 22(01): 12-18. Liu S W, Li S, Liu Y. Seal coating and evaluation of its abradability[J]. China Surface Engineering, 2009, 22(1): 12-18.
[4] Borel M O, A R Nicoll, H W Schlpfer, et al. The wear mechanisms occurring in abradable seals of gas turbines[J]. Surface and Coatings Technology, 1989, 39-40, Part 1(0): 117-126.
[5] Bill R C, L T Shiembob. Friction and wear of sintered fibermetal abradable seal materials[J]. Journal of Lubrication Technology-Transactions of the Asme, 1977, 99(4): 421-427.
[6] Dadouche A, M J Conlon, W Dmochowski, et al. Experimental evaluation of abradable seal performance at high temperature[M]. Proceedings of the Asme Turbo Expo 2008, Vol 5, Pt A, 2008:143-150.
[7] Taylor T A, B W Thompson, W Aton. High speed rub wear mechanism in IN-718 vs NiCrAl-Bentonite[J]. Surface & Coatings Technology, 2007, 202(4-7): 698-703.
[8] Bounazef M, S Guessasma, B Ait Saadi. The wear, deterioration and transformation phenomena of abradable coating BN-SiAl-bounding organic element, caused by the friction between the blades and the turbine casing[J]. Materials Letters, 2004, 58(27-28): 3 375-3 380.
[9] Stringer J, M B Marshall. High speed wear testing of an abradable coating[J]. Wear, 2012, 294-295: 257-263.
[10] 高禩洋, 刘阳, 段德莉, 等. 模拟封严涂层工况的刮擦式摩擦磨损试验机[J]. 中国表面工程, 2012, 25(4): 100-106. Gao S Y, Liu Y, Duan D L, et al. A rubbing type of friction and wear tester simulating working condition of seal coating[J]. China Surface Engineering, 2012, 25(4): 100-106.
[11] Wolak J, A F Emery, S Etemad, et al. Preliminary results on the abradability of porous, sintered seal material[J]. Journal of Lubrication Technology-Transactions of the Asme, 1983, 105(4): 576-584.
[12] 高禩洋, 刘夙伟, 李曙, 等. 单摆冲击划痕法对封严涂层耐磨性的评价[J]. 摩擦学学报, 2010, 30(04): 385-391. Gao S Y, Liu S W, Li S, et al. Evaluation of wear resistance of abradable coatings by a single-pass pendulum scratch method. Tribology, 2010, 30(4): 385-391.
[13] Collings E. The physical metallurgy of titanium alloys[J]. American Society for Metals, 1984.
[14] Emery A F, J Wolak, S Etemad, et al. An experimental investigation of temperatures due to rubbing at the blade-seal interface in an aircraft compressor[J]. Wear, 1983, 91(2): 117-130.
[15] Straffelini G, A Molinari. Dry sliding wear of Ti-6Al-4V alloy as influenced by the counterface and sliding conditions[J]. Wear, 1999, 236(1-2): 328-338.
[16] Ming Q, Z Yong-zhen, Y Jian-heng, et al. Microstructure and tribological characteristics of Ti-6Al-4V alloy against GCr15 under high speed and dry sliding[J]. Materials Science and Engineering: A, 2006, 434(1-2): 71-75.
[17] Mao Y S, L Wang, K M Chen, et al. Tribo-layer and its role in dry sliding wear of Ti-6Al-4V alloy[J]. Wear, 2013, 297(1-2): 1 032-1 039.
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