A review on dynamic characteristics of blade–casing rubbing

详细信息    查看全文

• 作者：Hui Ma ; Fanli Yin ; Yuzhu Guo ; Xingyu Tai ; Bangchun Wen
• 关键词：Rotating blade ; Bare casing ; Casing with abradable coating ; Rubbing ; Wear ; Dynamic characteristics
• 刊名：Nonlinear Dynamics
• 出版年：2016
• 出版时间：April 2016
• 年：2016
• 卷：84
• 期：2
• 页码：437-472
• 全文大小：4,858 KB
• 参考文献：1.Millecamps, A., Batailly, A., Legrand, M., et al.: Snecma’s viewpoint on the numerical and experimental simulation of blade-tip/casing unilateral contacts. In: ASME Turbo Expo 2015: Turbine Technical Conference and Exposition, American Society of Mechanical Engineers (2015)
  2.Aircraft Accident Report-National Airlines, Inc. DC-10-10, N60NA, Near Albuquerque, New Mexico, November 3, 1973, NTSB-AAR-75-2, National Transportation Safety Board, Washington (1975)
  3. http://​aviationweek.​com/​farnborough-2014/​blade-rubbing-root-f-35a-engine-fire
  4.Patel, T.H., Zuo, M.J., Zhao, X.M.: Nonlinear lateral-torsional coupled motion of a rotor contacting a viscoelastically suspended stator. Nonlinear Dyn. 69, 325–339 (2012)CrossRef
  5.Lu, W.X., Chu, F.L.: Radial and torsional vibration characteristics of a rub rotor. Nonlinear Dyn. 76, 529–549 (2014)MathSciNet CrossRef MATH
  6.Peletan, L., Baguet, S., Torkhani, M., et al.: Quasi-periodic harmonic balance method for rubbing self-induced vibrations in rotor-stator dynamics. Nonlinear Dyn. 78, 2501–2515 (2014)CrossRef
  7.Chu, S.M., Cao, D.Q., Sun, S.P., et al.: Impact vibration characteristics of a shrouded blade with asymmetric gaps under wake flow excitations. Nonlinear Dyn. 72, 539–554 (2013)MathSciNet CrossRef
  8.Muszynska, A.: Rotor to stationary element rub-related vibration phenomena in rotating machinery-literature survey. Shock Vib. Dig. 21, 3–11 (1989)CrossRef
  9.Ahmad, S.: Rotor casing contact phenomenon in rotor dynamics—literature survey. J. Vib. Control 16, 1369–1377 (2010)CrossRef
  10.Jiang, J., Chen, Y.H.: Advances in the research on nonlinear phenomena in rotor/stator rubbing systems. Adv. Mech. 43, 132–148 (2013). (in Chinese)
  11.Jacquet-Richardet, G., Torkhani, M., Cartraud, P., et al.: Rotor to stator contacts in turbomachines. Review and application. Mech. Syst. Signal Process. 40, 401–420 (2013)CrossRef
  12.Gilardi, G., Sharf, I.: Literature survey of contact dynamics modeling. Mech. Mach. Theory 37, 1213–1239 (2002)MathSciNet CrossRef MATH
  13.Padovan, J., Choy, F.K.: Nonlinear dynamics of rotor/blade/casing rub interactions. J. Turbomach. 109, 527–534 (1987)CrossRef
  14.Jiang, J., Ahrens, J., Ulbrich, H., et al.: A contact model of a rotating, rubbing blade. In: Proceedings of the 5th International Conference on Rotor Dynamics of the IFTOMM, Darmstadt, Germany, pp. 478–489 (1998)
  15.Ma, H., Tai, X.Y., Han, Q.K., et al.: A revised model for rubbing between rotating blade and elastic casing. J. Sound Vib. 337, 301–320 (2015)CrossRef
  16.Kascak, A.F., Tomko, J.J.: Effects of different rub models on simulated rotor dynamics. NASA Technical Paper 2220 (1984)
  17.Parent, M., Thouverez, F., Chevillot, F.: Whole engine interaction in a bladed rotor-to-stator contact. In: Proceedings of ASME Turbo Expo 2014: Turbine Technical Conference and Exposition, American Society of Mechanical Engineers (2014)
  18.Parent, M., Thouverez, F., Chevillot F.: 3D interaction in bladed rotor-to-stator contact. In: Proceedings of the 9th International Conference on Structural Dynamics, EURODYN 2014, Porto, Portugal, 30 June–2 July (2014)
  19.Lawrence, C., Carney, K., Gallardo, V.: A Study of Fan Stage/Casing Interaction Models. National Aeronautics and Space Administration, Glenn Research Center, NASA/TM—2003-212215 (2003)
  20.Thiery, F., Gustavsson, R., Aidanpaa, J.O.: Dynamics of a misaligned Kaplan turbine with blade-to-stator contacts. Int. J. Mech. Sci. 99, 251–261 (2015)CrossRef
  21.Zhao, Q., Yao, H.L., Wen, B.C.: Prediction method for steady-state response of local rubbing blade–rotor systems. J. Mech. Sci. Technol. 29(4), 1537–1545 (2015)CrossRef
  22.Yuan, H.Q., Kou, H.J.: Contact-impact analysis of a rotating geometric nonlinear plate under thermal shock. J. Eng. Math. 90(1), 119–140 (2015)MathSciNet CrossRef
  23.Petrov, E.: Multiharmonic analysis of nonlinear whole engine dynamics with bladed disc-casing rubbing contacts. In: ASME Turbo Expo 2012: Turbine Technical Conference and Exposition, American Society of Mechanical Engineers (2012)
  24.Petrov, E.: Analysis of bifurcations in multiharmonic analysis of nonlinear forced vibrations of gas-turbine engine structures with friction and gaps. In: ASME Turbo Expo 2015: Turbine Technical Conference and Exposition, American Society of Mechanical Engineers (2015)
  25.Sinha, S.K.: Non-linear dynamic response of a rotating radial Timoshenko beam with periodic pulse loading at the free-end. Int. J. Nonlinear Mech. 40, 113–149 (2005)CrossRef MATH
  26.Sinha, S.K.: Combined torsional-bending-axial dynamics of a twisted rotating cantilever Timoshenko beam with contact–impact loads at the free end. J. Appl. Mech. 74, 505–522 (2007)CrossRef MATH
  27.Turner, K., Adams, M., Dunn, M.: Simulation of engine blade tip-rub induced vibration. In: Proceedings of 2005-GT-68217 Ren-Tahoe, Nevada, USA (2005)
  28.Turner, K.E., Dunn, M., Padova, C.: Airfoil deflection characteristics during rub events. J. Turbomach. 134, 011018 (2012)CrossRef
  29.Kou, H.J., Yuan, H.Q.: Rub-induced non-linear vibrations of a rotating large deflection plate. Int. J. Nonlinear Mech. 58, 283–294 (2014)CrossRef
  30.Ma, H., Wang, D., Tai, X.Y., et al.: Vibration response analysis of blade–disk dovetail structure under blade tip rubbing condition. J. Vib. Control (2015). doi:10.​1177/​1077546315575835​
  31.Ma, Y.H., Cao, C., Zhang, D.Y., et al.: Constraint mechanical model and investigation for rub-impact in aero-engine system. In: ASME Turbo Expo 2015: Turbine Technical Conference and Exposition, American Society of Mechanical Engineers (2015)
  32.Lesaffre, N., Sinou, J.J., Thouverez, F.: Contact analysis of a flexible bladed-rotor. Eur. J. Mech. A-Solid. 26, 541–557 (2007)CrossRef MATH
  33.Sinha, S.K.: Dynamic characteristics of a flexible bladed-rotor with Coulomb damping due to tip-rub. J. Sound Vib. 273, 875–919 (2004)CrossRef
  34.Sinha, S.K.: Rotordynamic analysis of asymmetric turbofan rotor due to fan blade-loss event with contact–impact rub loads. J. Sound Vib. 332, 2253–2283 (2013)CrossRef
  35.Legrand, M., Pierre, C., Peseux, B.: Structural modal interaction of a four degree of freedom bladed disk and casing model. J. Comput. Nonlinear Dyn. 5, 13–41 (2010)CrossRef
  36.Legrand, M., Pierre, C., Cartraud, P., et al.: Two-dimensional modeling of an aircraft engine structural bladed disk–casing modal interaction. J. Sound Vib. 319, 366–391 (2009)CrossRef
  37.Batailly, A., Legrand, M., Cartraud, P., et al.: Assessment of reduced models for the detection of modal interaction through rotor stator contacts. J. Comput. Nonlinear Dyn. 329, 5546–5562 (2010)
  38.Salvat, N., Batailly, A., Legrand, M.: Two-dimensional modeling of shaft precessional motions induced by blade/casing unilateral contact in aircraft engines. In: ASME Turbo Expo 2014: Turbine Technical Conference and Exposition, American Society of Mechanical Engineers (2014)
  39.Almeida, P., Gibert, G., Thouverez, F., et al.: On some physical phenomena involved in blade–casing contact. In: Proceedings of the 9th International Conference on Structural Dynamics, EURODYN 2014, Porto, Portugal, 30 June–2 July (2014)
  40.Legrand, M., Batilly, A., Magnain, B., et al.: Full three-dimensional investigation of structural contact interactions in turbomachines. J. Sound Vib. 331, 2578–2601 (2012)CrossRef
  41.Batailly, A., Meingast, M., Legrand, M., et al.: Rotor–stator interaction scenarios for the centrifugal compressor of a helicopter engine. In: ASME IDETC Conference, Portland, United States (2013)
  42.Batailly, A., Meingast, M., Legrand, M.: Unilateral contact induced blade/casing vibratory interactions in impellers: analysis for rigid casings. J. Sound Vib. 337, 244–262 (2015)CrossRef
  43.Meingast, M.B., Legrand, M., Pierre, C.: A linear complementarity problem formulation for periodic solutions to unilateral contact problems. Int. J. Nonlinear Mech. 66, 18–27 (2014)CrossRef
  44.Ma, H., Tai, X.Y., Niu, H.Q., et al.: Numerical research on rub-impact fault in a blade–rotor–casing coupling system. J. Vibroeng. 15, 1477–1489 (2013)
  45.Arnoult, E., Guilloteau, I., Peseux, B., et al.: A new contact finite element coupled with an analytical search of contact. In: European Congress on Computational Methods in Applied Sciences and Engineering ECCOMAS 2000, Barcelona, 11–14 Sept (2000)
  46.Garza, J.W.: Tip rub induced blade vibrations: experimental and computational results. Master’s thesis, The Ohio State University, USA (2006)
  47.Arzina, D.: Vibration analysis of compressor blade tip-rubbing. Master’s thesis, School of Engineering, Cranfield University, Cranfield (2011)
  48.Cao, D.Q., Yang, Y., Chen, H.T., et al.: A novel contact force model for the impact analysis of structures with coating and its experimental verification. Mech. Syst. Signal Process. 70–71, 1056–1072 (2016)CrossRef
  49.Salvat, N., Batailly, A., Legrand, M.: Modeling of abradable coating removal in aircraft engines through delay differential equations. J. Eng. Gas Turbines Power 135, 102102 (2013)CrossRef
  50.Olgac, N., Zalluhoglu, U., Kammer, A.S.: On blade/casing rub problems in turbomachinery: an efficient delayed differential equation approach. J. Sound Vib. 333, 6662–6675 (2014)CrossRef
  51.Williams, R.J.: Simulation of blade casing interaction phenomena in gas turbines resulting from heavy tip rubs using an implicit time marching method. In: Proceedings of ASME Turbo Expo 2011, GT2011-45495, Vancouver, June (2011)
  52.Ronchi, M., Williams, R. J., Pennacchi, P.: An improved simulation method for blade–casing interaction phenomena. In: 10th International Conference on Vibrations in Rotating Machinery, IMechE London, 11–13 Sept (2012)
  53.Legrand, M., Barailly, A., Pierre, C.: Numerical investigation of abradable coating removal in aircraft engines through plastic constitutive law. J. Comput. Nonlinear Dyn. 7, 011010.1-11 (2012)CrossRef
  54.Batailly, A., Legrand, M., Millecamps, A., et al.: Numerical-experimental comparison in the simulation of rotor/stator interaction through blade-tip/abradable coating contact. J. Eng. Gas Turbines Power 134, 082504.1–082504.11 (2012)CrossRef
  55.Batailly, A., Cuny, M., Legrand, M., et al.: Numerical-experimental confrontation in the simulation of tool/abradable material interaction. J. Eng. Gas Turbines Power 135, 062102.1-10 (2013)CrossRef
  56.Batailly, A., Legrand, M.: Conjectural bifurcation analysis of an aircraft engine blade undergoing 3d unilateral contact constraints. In: ASME Turbo Expo 2014: Turbine Technical Conference and Exposition, American Society of Mechanical Engineers (2014)
  57.Batailly, A., Legrand, M., Millecamps, A., et al.: Conjectural bifurcation analysis of the contact-induced vibratory response of an aircraft engine blade. J. Sound Vib. 348, 239–262 (2015)CrossRef
  58.Batailly, A., Legrand, M., Millecamps, A., et al.: Redesign of a high-pressure compressor blade accounting for nonlinear structural interactions. J. Eng. Gas Turbines Power 137, 022502.1-8 (2015)
  59.Almeida, P., Gibert, C., Thouverezet, F., et al.: Numerical analysis of bladed disk–casing contact with friction and wear. In: ASME Turbo Expo 2015: Turbine Technical Conference and Exposition, American Society of Mechanical Engineers (2015)
  60.Archard, J.F.: Contact and rubbing of flat surfaces. J. Appl. Phys. 24(8), 981–988 (1953)CrossRef
  61.Beaupain, O., Jeunechamps, P.P., Ponthot, J.P.: Numerical simulation of blade/casing rub interaction. In: European Workshop on New Aero Engine Concepts, Munich, 30 June–1 July (2010)
  62.Chai, X.H., Han, P.L., Shi, T.C., et al.: The study of tip clearance of a wide-chord fan blade of a high bypass ratio turbo-fan engine. In: Proceedings of ASME Turbo Expo 2014: Turbine Technical Conference and Exposition GT2014, Düsseldorf, Germany, 16–20 June (2014)
  63.Wei, F.F., Chen, Y.Y., Wu, Z.Q., et al.: Failure analysis of rubbing of the fan tip and case of an engine. Procedia Eng. 99, 1289–1296 (2015)CrossRef
  64.Lesaffre, N., Sinou, J.J., Thouverez, F.: Stability analysis of rotating beams rubbing on an elastic circular structure. J. Sound Vib. 299, 1005–1032 (2007)CrossRef
  65.Kennedy, F.E.: Single pass rub phenomena analysis and experiment. J. Lubr. Technol. 104, 582–588 (1982)CrossRef
  66.Wang, B., Zheng, J., Lu, G.: Rubbing contact between rotating blade and casing plate, part 1-experimental study. Key Eng. Mater. 233–236, 725–730 (2003)CrossRef
  67.Jiang, J.: Investigation of friction in blade/casing rub and its effect on dynamics of a rotor with rub. Doctor’s thesis, Shaker Verlag GmbH, German (2001)
  68.Ahrens, J., Ulbrich, H., Ahaus, G.: Measurement of contact forces during blade rubbing. In: Vibrations in Rotating Machinery, 7th International Conference, Nottingham, pp. 259–268. ImechE, London (2000)
  69.Abdelrhman, A.M., Leong, M.S., Hee, L.M., et al.: Application of wavelet analysis in blade faults diagnosis for multi-stages rotor system. Appl. Mech. Mater. 393, 959–964 (2013)CrossRef
  70.Padova, C., Barton, J., Dunn, M.G., et al.: Development of an experimental capability to produce controlled blade tip/shroud rubs at engine speed. J. Turbomach. 127, 726–735 (2005)CrossRef
  71.Padova, C., Barton, J., Dunn, M.G., et al.: Experimental results from controlled blade tip/shroud rubs at engine speed. J. Turbomach. 129, 713–723 (2007)CrossRef
  72.Langenbrunner, N., Weaver, M., Dunn, M.G., et al.: Dynamic response of a metal and a CMC turbine blade during a controlled rub event using a segmented shroud. J. Eng. Gas. Turbines Power-Trans. ASME 137(6), 062504 (2015)CrossRef
  73.Chen, G.: Study on the recognition of aero-engine blade–casing rubbing fault based on the casing vibration acceleration. Measurement 65, 71–80 (2015)CrossRef
  74.Chen, G.: Characteristics analysis of blade–casing rubbing based on casing vibration acceleration. J. Mech. Sci. Technol. 29(4), 1513–1526 (2015)CrossRef
  75.Laverty, W.: Rub energetics of compressor blade tip seals. Wear 75(1), 1–20 (1982)CrossRef
  76.Borel, M.O., Nicoll, A.R., Schlapfer, H.W.: The wear mechanisms occurring in abradable seals of gas turbines. Surf. Coat. Technol. 39–40, 117–126 (1989)CrossRef
  77.Zheng, N.X., Daubler, M.A., Schweitzer, K.K., et al.: Development of air seal systems for modern jet engines. http://​www.​engine-maintenance.​info/​en/​technologies/​engineering_​news/​development/​/​Zheng_​Dglr2003_​seal_​system.​pdf (2003)
  78.Rathmann, U., Olmes, S., Simeon, A.: Sealing technology—rub test rig for abrasive/abradable systems. In: ASME Turbo Expo 2007, Draft GT2007-27724 (2007)
  79.Irissou, E., Dadouche, A., Lima, R.S.: Tribological characterization of plasma-sprayed CoNiCrAIY-BN abradable coatings. J. Therm. Spray Technol. 23, 252–261 (2014)CrossRef
  80.Xue, W.H., Gao, S.Y., Duan, D.L., et al.: Material transfer behaviour between a Ti6Al4V blade and an aluminium hexagonal boron nitride abradable coating during high-speed rubbing. Wear 322–323, 76–90 (2015)CrossRef
  81.Padova, C., Dunn, M.G., Barton, J., et al.: Casing treatment and blade-tip configuration effects on controlled gas turbine blade tip/shroud rubs at engine conditions. J. Turbomach. 133, 011016.1-12 (2011)CrossRef
  82.Millecamps, A., Brunel, J.F., Dufrenoy, P., et al.: Influence of thermal effects during blade–casing contact experiments. In: Proceedings of the ASME 2009 International Design Engineering Technical Conferences & Computers and Information in Engineering Conference, IDECT/CIE 2009, DETC2009-86842, San Diego, California, USA (2009)
  83.Reiss, H.: Flow Control Core, Overview European Workshop on New Aero Engine Concepts, Munich, 30 June–1 July (2010)
  84.Almeida, P., Gibert, C., Thouverez, F., et al.: Experimental analysis of dynamic interaction between a centrifugal compressor and its casing. J. Turbomach. 137, 031008.1-10 (2015)
  85.Stringer, J., Marshall, M.B.: High speed wear testing of an abradable coating. Wear 294–295, 257–263 (2012)CrossRef
  86.Fois, N., Stringer, J., Marshall, M.B.: Adhesive transfer in aero-engine abradable linings contact. Wear 304, 202–210 (2013)CrossRef
  87.Fois, N., Watson, M., Stringer, J., et al.: An investigation of the relationship between wear and contact force for abradable materials. Proc. Inst. Mech. Eng. J-J. Eng. 229(2), 136–150 (2015)CrossRef
  88.Watson, M., Fois, N., Marshall, M.B.: Effects of blade surface treatments in tip–shroud abradable contacts. Wear 338, 268–281 (2015)CrossRef
  89.Baiz, S., Fabis, J., Boidin, X., et al.: Experimental investigation of the blade/seal interaction. Proc. Inst. Mech. Eng. J-J. Eng. 227, 980–995 (2013)CrossRef
  90.Mandarda, R., Witz, J.F., Boidin, X., et al.: Interacting force estimation during blade/seal rubs. Trobol. Int. 82, 504–513 (2015)CrossRef
  91.Mandard, R., Witz, J.F., Desplanques, Y., et al.: Wavelet analysis of experimental blade vibrations during interaction with an abradable coating. J. Tribol. 136, 031102.1-13 (2014)
  92.Sutter, G., Philipponb, S., Garcin, F.: Dynamic analysis of the interaction between an abradable material and a titanium alloy. Wear 261, 686–692 (2006)CrossRef
  93.Cuny, M., Philippon, S., Chevrier, P., et al.: Experimental measurement of dynamic forces generated during short-duration contacts: application to blade–casing interactions in aircraft engines. Exp. Mech. 54, 101–114 (2014)CrossRef
  94.Astashev, V.K., Babitsky, V.I.: Ultrasonic Processes and Machines: Dynamics, Control and Applications. Springer, Berlin (2007)MATH
  95.Petrov, E.P.: Reduction of forced response levels for bladed discs by mistuning: overview of the phenomenon. In: Proceedings of ASME Turbo Expo 2010: Power for Land, Sea and Air GT2010, Glasgow (2010)
  96.Ma, H., Lu, Y., Wu, Z.Y., et al.: A new dynamic model of rotor–blade systems. J. Sound Vib. 357, 168–194 (2015)CrossRef
  97.Fan, S.C., Tang, X.H., Zhang, Y.D., et al.: Failure analysis of third-stage rotor blade of high-pressure compressor in aero-engine. Fail. Anal. Prev. 9, 110–114 (2014). (in Chinese)
  98.Peyraut, F., Seichepine, J.L., Coddet, C., et al.: Finite element modeling of abradable materials—identification of plastic parameters and issues on minimum hardness against coating’s thickness. Int. J. Simul. Multidiscip. Des. Optim. 2, 209–215 (2008)CrossRef
  
• 作者单位：Hui Ma (1)
  Fanli Yin (1)
  Yuzhu Guo (2)
  Xingyu Tai (3)
  Bangchun Wen (1)
  
  1. School of Mechanical Engineering and Automation, Northeastern University, Shenyang, 110819, Liaoning, People’s Republic of China
  2. Department of Automatic Control and Systems Engineering, The University of Sheffield, Sheffield, S1 3JD, UK
  3. Shenyang Blower Works Group Corporation, Shenyang, 110869, People’s Republic of China
  
• 刊物类别：Engineering
• 刊物主题：Vibration, Dynamical Systems and Control
  Mechanics
  Mechanical Engineering
  Automotive and Aerospace Engineering and Traffic
  
• 出版者：Springer Netherlands
• ISSN：1573-269X

文摘

Blade–casing interaction/rubbing can occur under the small blade-tip clearance, which may lead to the rubbing damage, excessive wear of the abradable coating, and efficiency loss caused by the increasing tip leakage flow. Moreover, the rubbing process involves complicated dynamic phenomena, such as friction-induced wear and heat, coupling vibration of the blade and elastic casing, which has recently received a great concern. This paper provides a review on the dynamic characteristics of blade, rotor, and casing as well as the mechanism of coating wear when the rubbing between the blade and bare or coating casing occurs. Firstly, the modeling methods for blade–casing rubbing are categorized into three types in accordance with different casing types, namely models for the rubbing between the blade and bare casing, models for the rubbing between the blade and coating casing without considering wear, and models for the rubbing between the blade and coating casing considering wear. Then, the simulated blade–casing dynamic characteristics due to rubbing are described for both bare and coating casings. After that, the experimental results of the blade–casing rubbing are reviewed and summarized for the bare and coating casings, respectively. Finally, the open problems for blade–casing rubbings are stated, and some recommendations for future research are also pointed out.