| Citation: | LIU Linchuan, HOU Cheng, FAN Xueling, ZHOU Ziyang. A Simplified Load Analysis Method and Load Characteristics of Coated Turbine Blades[J]. Applied Mathematics and Mechanics, 2026, 47(6): 723-735. doi: 10.21656/1000-0887.460201 |
|
[2]王铁军, 范学领, 丁秉钧, 等.热障涂层强度理论与检测技术[M]. 西安: 西安交通大学出版社, 2016. (WANG Tiejun, FAN Xueling, DING Bingjun, et al.Strength Theory and Testing Technology of Thermal Barrier Coatings[M]. Xi’an: Xi’an Jiaotong University Press, 2016. (in Chinese))
|
|
PADTURE N P, GELL M, JORDAN E H. Thermal barrier coatings for gas-turbine engine applications[J].Science,2002,296(5566): 280-284.
|
|
[3]LIU L, FU S, HU Z, et al. Thermo-mechanical analysis of TBC-film cooling system under high blowing ratio considering the effects of curvature[J].Surface and Coatings Technology,2023,470: 129826.
|
|
[4]柴怡君, 林晨, 李跃明. 考虑化学氧化效应时热障涂层氧化物的生长规律[J]. 应用数学和力学, 2015,36(4): 404-413. (CHAI Yijun, LIN Chen, LI Yueming. Growth trend of thermal grown oxide in TBCs under chemical oxidation effect[J].Applied Mathematics and Mechanics,2015,36(4): 404-413. (in Chinese))
|
|
[5]LIU L, WU J, HU Z, et al. Thermal analysis of turbine blades with thermal barrier coatings using virtual wall thickness method[J].Computer Modeling in Engineering & Sciences,2023,134(2): 1219-1236.
|
|
[6]WANG X M, HUI Y Z, HOU Y Y, et al. Direct investigation on high temperature tensile and creep behavior at different regions of directional solidified cast turbine blades[J].Mechanics of Materials,2019,136: 103068.
|
|
[7]RANI S, AGRAWAL A K, RASTOGI V. Failure analysis of a first stage IN738 gas turbine blade tip cracking in a thermal power plant[J].Case Studies in Engineering Failure Analysis,2017,8: 1-10.
|
|
[8]CHUNG H, SOHN H S, PARK J S, et al. Thermo-structural analysis of cracks on gas turbine vane segment having multiple airfoils[J].Energy,2017,118: 1275-1285.
|
|
[9]QU S, FU C M, DONG C, et al. Failure analysis of the 1st stage blades in gas turbine engine[J].Engineering Failure Analysis,2013,32: 292-303.
|
|
[10]KARGARNEJAD S, DJAVANROODI F. Failure assessment of Nimonic 80A gas turbine blade[J].Engineering Failure Analysis,2012,26: 211-219.
|
|
[11]WANG L, LI D C, YANG J S, et al. Modeling of thermal properties and failure of thermal barrier coatings with the use of finite element methods: a review[J].Journal of the European Ceramic Society,2016,36(6): 1313-1331.
|
|
[12]WANG Z, WANG D, LIU Z, et al. Numerical analysis on effects of inlet pressure and temperature non-uniformities on aero-thermal performance of a HP turbine[J].International Journal of Heat and Mass Transfer,2017,104: 83-97.
|
|
[13]MAIKELL J, BOGARD D, PIGGUSH J, et al. Experimental simulation of a film cooled turbine blade leading edge including thermal barrier coating effects[J].Journal of Turbomachinery,2011,133: 011014.
|
|
[14]LV B, JIN X, CAO J, et al. Advances in numerical modeling of environmental barrier coating systems for gas turbines[J].Journal of the European Ceramic Society,2020,40(9): 3363-3379.
|
|
[15]ZHU W, WANG J W, YANG L, et al. Modeling and simulation of the temperature and stress fields in a 3D turbine blade coated with thermal barrier coatings[J].Surface and Coatings Technology,2017,315: 443-453.
|
|
[16]JI Y, MA C, GE B, et al. Conjugate heat transfer investigation on the cooling performance of air cooled turbine blade with thermal barrier coating[J].Journal of Thermal Science,2016,25(4): 325-335.
|
|
[17]SHEN Q, LI S Z, YANG L, et al. Coupled mechanical-oxidation modeling during oxidation of thermal barrier coatings[J].Computational Materials Science,2018,154: 538-546.
|
|
[18]SONG J, QI H, SHI D, et al. Effect of non-uniform growth of TGO layer on cracking behaviors in thermal barrier coatings: a numerical study[J].Surface and Coatings Technology,2019,370: 113-124.
|
|
[19]ZHU W, CAI M, YANG L, et al. The effect of morphology of thermally grown oxide on the stress field in a turbine blade with thermal barrier coatings[J].Surface & Coatings Technology,2015,276: 160-167.
|
|
[20]LI B, FAN X, LI D, et al. Design of thermal barrier coatings thickness for gas turbine blade based on finite element analysis[J].Mathematical Problems in Engineering,2017,2017(1): 2147830.
|
|
[21]VO D T, MAI T D, KIM B, et al. Numerical study on the influence of coolant temperature, pressure, and thermal barrier coating thickness on heat transfer in high-pressure blades[J].International Journal of Heat and Mass Transfer,2022,189: 122715.
|
|
[22]BALINT D, HUTCHINSON J. An analytical model of rumpling in thermal barrier coatings[J].Journal of the Mechanics and Physics of Solids,2005,53(4): 949-973.
|
|
[23]BALINT D S, KIM S S, LIU Y F, et al. Anisotropic TGO rumpling in EB-PVD thermal barrier coatings under in-phase thermomechanical loading[J].Acta Materialia,2011,59(6): 2544-2555.
|
|
[24]JIANG J, MA X, WANG B. Stress analysis of the thermal barrier coating system near a cooling hole considering the free-edge effect[J].Ceramics International,2020,46(1): 331-342.
|
|
[25]VAUNOIS J R, DORVAUX J M, KANOUT P, et al. A new version of a rumpling predictive model in thermal barrier coatings[J].European Journal of Mechanics A,2013,42: 402-421.
|
|
[26]DRYEPONDT S, PORTER J R, CLARKE D R. On the initiation of cyclic oxidation-induced rumpling of platinum-modified nickel aluminide coatings[J].Acta Materialia,2009,57(6): 1717-1723.
|
|
[27]TOLPYGO V, CLARKE D. On the rumpling mechanism in nickel-aluminide coatings, part Ⅱ: characterization of surface undulations and bond coat swelling[J].Acta Materialia,2004,52(17): 5129-5141.
|
|
[28]SMETANKINA N V, POSTNYI O V, MERKULOVA A I, et al. Modeling of non-stationary temperature fields in multilayer shells with film heat sources[C]//2020 IEEE KhPI Week on Advanced Technology (KhPI Week). Kharkiv, Ukraine: IEEE, 2020: 242-246.
|
|
[29]BERGMAN T.Fundamentals of Heat and Mass Transfer[M]. Hoboken: John Wiley & Sons, 2011.
|
|
[30]LIU L, FAN X, CHU Z, et al. Thermo-mechanical loads and creep life assessment for coated turbine blades considering the influence of cooling hole blockage[J].Engineering Failure Analysis,2025,170: 109321.
|
|
[31]TRAEGER F, VAEN R, RAUWALD K H, et al. Thermal cycling setup for testing thermal barrier coatings[J].Advanced Engineering Materials,2003,5(6): 429-432.
|
|
[32]EVANS H E. Oxidation failure of TBC systems: an assessment of mechanisms[J].Surface and Coatings Technology,2011,206(7): 1512-1521.
|
|
[33]中国金属学会高温材料分会. 中国高温合金手册[M]. 北京: 中国标准出版社, 2012. (The High Temperature Materials Branch of The Chinese Society for Metals.China Superalloys Handbook[M]. Beijing: Standards Press of China, 2012. (in Chinese))
|
|
[34]CAI L, HE Y, WANG S, et al. Thermal-fluid-solid coupling analysis on the temperature and thermal stress field of a nickel-base superalloy turbine blade[J].Materials,2021,14(12): 3315.
|