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WANG Anzhe, WANG Shuai, ZHAO Xinyuan, ZHANG Jie, CHENG Yehong, ZHOU Peng. Research Progress in Strength Prediction of Ceramic Materials with Flaws[J]. Materials and Mechanical Engineering, 2023, 47(10): 1-8. DOI: 10.11973/jxgccl202310001
Citation: WANG Anzhe, WANG Shuai, ZHAO Xinyuan, ZHANG Jie, CHENG Yehong, ZHOU Peng. Research Progress in Strength Prediction of Ceramic Materials with Flaws[J]. Materials and Mechanical Engineering, 2023, 47(10): 1-8. DOI: 10.11973/jxgccl202310001

Research Progress in Strength Prediction of Ceramic Materials with Flaws

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  • Received Date: August 21, 2022
  • Revised Date: August 02, 2023
  • Ceramics have numerous excellent properties such as low density, high hardness and wear resistance, but their practical applications in the structural materials field are still extremely cautious. The fundamental reasons are the flaw sensitivity of ceramics and the imperfect theory of ceramic failure prediction. The common flaws in the process of ceramic preparation are introduced, and the physical nature of the random distribution of ceramic strength is analyzed, and then the research status of strength prediction in ceramics under the action of flaws is summarized. It is pointed out that non-destructive testing, in-situ testing and computer simulation technology could be comprehensively used in the future to explore the mechanism of flaw inducing cracking and the quantitative law of ceramic-strength response, and meanwhile attention should be paid to the influence of flaws on ceramic-strength in the actual service environment(fatigue, thermal shock, etc.).
  • [1]
    陈琪,李同起,张大海,等.ZrB2材料的制备工艺与应用[J].硅酸盐通报,2020,39(3):873-884.

    CHEN Q,LI T Q,ZHANG D H,et al.Preparation process and application of ZrB2 materials[J].Bulletin of the Chinese Ceramic Society,2020,39(3):873-884.
    [2]
    GOLLA B R,MUKHOPADHYAY A,BASU B,et al.Review on ultra-high temperature boride ceramics[J].Progress in Materials Science,2020,111:100651.
    [3]
    SHI H T,LI Y Y,BAI X T,et al.Investigation of the orbit-spinning behaviors of the outer ring in a full ceramic ball bearing-steel pedestal system in wide temperature ranges[J].Mechanical Systems and Signal Processing,2021,149:107317.
    [4]
    WANG H Y,HU K H,LU K A,et al.Experimental and numerical analysis on the leading-edge bulge effect during the recoating process in ceramic stereolithography[J].Additive Manufacturing,2022,51:102652.
    [5]
    BLÁZQUEZ-CARMONA P,SANZ-HERRERA J A,MARTÍNEZ-VÁZQUEZ F J,et al.Structural optimization of 3D-printed patient-specific ceramic scaffolds for in vivo bone regeneration in load-bearing defects[J].Journal of the Mechanical Behavior of Biomedical Materials,2021,121:104613.
    [6]
    LAWN B R.Fracture of brittle solids[M].2nd ed.Cambridge:Cambridge University Press,1993.
    [7]
    ENGEL U,HVBNER H.Strength improvement of cemented carbides by hot isostatic pressing (HIP)[J].Journal of Materials Science,1978,13(9):2003-2012.
    [8]
    NEUMAN E W,HILMAS G E,FAHRENHOLTZ W G.Mechanical behavior of zirconium diboride-silicon carbide-boron carbide ceramics up to 2200℃[J].Journal of the European Ceramic Society,2015,35(2):463-476.
    [9]
    CHAMBERLAIN A L,FAHRENHOLTZ W G,HILMAS G E,et al.High-strength zirconium diboride-based ceramics[J].Journal of the American Ceramic Society,2004,87(6):1170-1172.
    [10]
    龚江宏.陶瓷材料脆性断裂的显微结构效应[J].现代技术陶瓷,2021,42(增刊2):287-428.

    GONG J H.Microstructural effects in brittle fracture of ceramics[J].Advanced Ceramics,2021,42(S2):287-428.
    [11]
    KUDYBA-JANSEN A A,HINTZEN H T,METSELAAR R.The influence of green processing on the sintering and mechanical properties of β-sialon[J].Journal of the European Ceramic Society,2001,21(12):2153-2160.
    [12]
    SCHERRER S S,LOHBAUER U,DELLA BONA A,et al.ADM guidance-Ceramics:Guidance to the use of fractography in failure analysis of brittle materials[J].Dental Materials,2017,33(6):599-620.
    [13]
    王安哲.硼化锆基超高温陶瓷材料力学性能的精确表征及方法研究[D].哈尔滨:哈尔滨工业大学,2018. WANG A Z.Accurate characterization and method study on the mechanical properties of zirconium boride based ultra-high temperature ceramics[D].Harbin:Harbin Institute of Technology,2018.
    [14]
    丁尧.ZrB2基超高温陶瓷无损检测研究[D].哈尔滨:哈尔滨工业大学,2015. DING Y.Non-destructive testing research of ZrB2-based ultra high temperature ceramics[D].Harbin:Harbin Institute of Technology,2015.
    [15]
    ZHANG C G,HU X Z,SERCOMBE T,et al.Prediction of ceramic fracture with normal distribution pertinent to grain size[J].Acta Materialia,2018,145:41-48.
    [16]
    YANG S G,ZHANG C G,ZHANG X C.Probabilistic relation between stress intensity and fracture toughness in ceramics[J].Ceramics International,2020,46(12):20558-20564.
    [17]
    OZAKI S,AOKI Y,OSADA T,et al.Finite element analysis of fracture statistics of ceramics:Effects of grain size and pore size distributions[J].Journal of the American Ceramic Society,2018,101(7):3191-3204.
    [18]
    OZAKI S,YAMAGATA K,ITO C,et al.Finite element analysis of fracture behavior in ceramics:Prediction of strength distribution using microstructural features[J].Journal of the American Ceramic Society,2022,105(3):2182-2195.
    [19]
    TAKEO K,AOKI Y,OSADA T,et al.Finite element analysis of the size effect on ceramic strength[J].Materials,2019,12(18):2885.
    [20]
    NAKAMURA S,TANAKA S,KATO Z,et al.Strength-processing defects relationship based on micrographic analysis and fracture mechanics in alumina ceramics[J].Journal of the American Ceramic Society,2009,92(3):688-693.
    [21]
    COOK R F,DELRIO F W.Determination of ceramic flaw populations from component strengths[J].Journal of the American Ceramic Society,2019,102(8):4794-4808.
    [22]
    HOGAN J D,FARBANIEC L,SANO T,et al.The effects of defects on the uniaxial compressive strength and failure of an advanced ceramic[J].Acta Materialia,2016,102:263-272.
    [23]
    INGLIS C E.Stresses in a plate due to the presence of cracks and sharp corners[J].Transactions of the Institute of Naval Architects,1913,55:193-198.
    [24]
    LANGE F F.Fracture mechanics and microstructural design[M]//BRADT R C,HASSELMAN D P H,LANGE F F.Crack Growth and Microstructure.Boston,MA:Springer US,1978:799-819.
    [25]
    IRWIN G R.Crack-extension force for a part-through crack in a plate[J].Journal of Applied Mechanics,1962,29(4):651-654.
    [26]
    SMITH F W,ALAVI M J.Stress intensity factors for a penny shaped crack in a half space[J].Engineering Fracture Mechanics,1971,3(3):241-254.
    [27]
    STONESIFER R B,BRUST F W,LEIS B N.Mixed-mode stress intensity factors for interacting semi-elliptical surface cracks in a plate[J].Engineering Fracture Mechanics,1993,45(3):357-380.
    [28]
    KOBAYASHI A S,POLVANICH N,EMERY A F,et al.Surface flaws in a plate in bending[C]//Society of Engineering Science,Annual Meeting.Austin, Texas:[s.n.],1975:343-352.
    [29]
    KATHIRESAN K.Three-dimensional linear elastic fracture mechanics analysis by a displacement hybrid finite element model[D].Atlanta:Georgia Institute of Technology,1976.
    [30]
    RAJU I S,NEWMAN J C Jr.Improved stress-intensity factors for semi-elliptical surface cracks in finite-thickness plates[C]//The 4th International Conference on Structural Mechanics in Reactor Technology.San Francisco,CA:NASA,1977.
    [31]
    RAJU I S,NEWMAN J C Jr.Stress-intensity factors for a wide range of semi-elliptical surface cracks in finite-thickness plates[J].Engineering Fracture Mechanics,1979,11(4):817-829.
    [32]
    NEWMAN J C Jr,RAJU I S.An empirical stress-intensity factor equation for the surface crack[J].Engineering Fracture Mechanics,1981,15(1/2):185-192.
    [33]
    STROBL S,SUPANCIC P,LUBE T,et al.Surface crack in tension or in bending:A reassessment of the Newman and Raju formula in respect to fracture toughness measurements in brittle materials[J].Journal of the European Ceramic Society,2012,32(8):1491-1501.
    [34]
    YUKITAKA M,MASAHIRO E.Quantitative evaluation of fatigue strength of metals containing various small defects or cracks[J].Engineering Fracture Mechanics,1983,17(1):1-15.
    [35]
    ANDO K,KIM B A,IWASA M,et al.Process zone size failure criterion and probabilistic fracture assessment curves for ceramics[J].Fatigue & Fracture of Engineering Materials and Structures,1992,15(2):139-149.
    [36]
    SATO N,TAKAHASHI K.Evaluation of fracture strength of ceramics containing small surface defects introduced by focused ion beam[J].Materials,2018,11(3):457.
    [37]
    WANG A,HU P,ZHAO X,et al.Modelling and experimental investigation of pore-like flaw-strength response in structural ceramics[J].Ceramics International,2020,46(10):14431-14438.
    [38]
    GÓMEZ F J,GUINEA G V,ELICES M.Failure criteria for linear elastic materials with U-notches[J].International Journal of Fracture,2006,141(1):99-113.
    [39]
    YANG S G,ZHANG C G,ZHANG X C.Notch radius effect on fracture toughness of ceramics pertinent to grain size[J].Journal of the European Ceramic Society,2020,40(12):4217-4223.
    [40]
    ZHAO X Y,WANG A Z,CHEN Y Y,et al.Quantitative strength prediction of advanced ceramics with regular/irregular flaws in I-mode failure condition[J].Ceramics International,2021,47(22):31527-31535.
    [41]
    ERDOGAN F,SIH G C.On the crack extension in plates under plane loading and transverse shear[J].Journal of Basic Engineering,1963,85(4):519-525.
    [42]
    PETROVIC J J,MENDIRATTA M G.Mixed-mode fracture from controlled surface flaws in hot-pressed Si3N4[J].Journal of the American Ceramic Society,1976,59(3/4):163-167.
    [43]
    FREIMAN S W,GONZALEZ A C,MECHOLSKY J J.Mixed-mode fracture in soda-lime glass[J].Journal of the American Ceramic Society,1979,62(3/4):206-208.
    [44]
    WANG A Z,ZHAO X Y,HUANG M X,et al.A quantitative study of flaw/strength response in ultra-high temperature ceramics based on femtosecond laser method[J].Theoretical and Applied Fracture Mechanics,2020,110:102775.
    [45]
    TANIGUCHI Y,KITAZUMI J,YAMADA T.Bending strength analysis of ceramics based on the statistical theory of stress and fracture location[J].Journal of the Society of Materials Science,Japan,1989,38(430):777-782.
    [46]
    SAKAMOTO F,TAKAHASHI T,TATAMI J,et al.Prediction of strength based on defect analysis in Al2O3 ceramics via non-destructive and three-dimensional observation using optical coherence tomography[J].Journal of the Ceramic Society of Japan,2019,127(7):462-468.
    [47]
    FLINN B D,BORDIA R K,ZIMMERMANN A,et al.Evolution of defect size and strength of porous alumina during sintering[J].Journal of the European Ceramic Society,2000,20(14/15):2561-2568.
    [48]
    WANG A Z,HU P,DU B,et al.Effect of collinear flaws on flexural strength and fracture behavior of ZrB2-SiC ceramic[J].Ceramics International,2017,43(16):14488-14492.
    [49]
    WANG A Z,DU B,HU P,et al.Accurate evaluation of critical flaw size in structural ceramics via femtosecond laser[J].Ceramics International,2018,44(18):23008-23013.
    [50]
    MIRKHALAF M,DASTJERDI A K,BARTHELAT F.Overcoming the brittleness of glass through bio-inspiration and micro-architecture[J].Nature Communications,2014,5:3166.
    [51]
    ZHAO Z K.Review of non-destructive testing methods for defect detection of ceramics[J].Ceramics International,2021,47(4):4389-4397.
    [52]
    肖强宏,周强,王莹,等.一种基于敲击声时-频分析的陶瓷结构缺陷检测方法研究[J].中国陶瓷,2017,53(9):47-53.

    XIAO Q H,ZHOU Q,WANG Y,et al.Research on detecting method of ceramic structure defect based on coin-tap sound time-frequency analysis[J].China Ceramics,2017,53(9):47-53.
    [53]
    赵海涛,褚亮.基于声发射的陶瓷材料损伤和增韧特性研究[J].中国陶瓷,2017,53(12):39-45.

    ZHAO H T,CHU L.Damage and toughening characteristics of ceramic by acoustic emission method[J].China Ceramics,2017,53(12):39-45.
    [54]
    SFARRA S,IBARRA-CASTANEDO C,BENDADA A,et al.Comparative study for the nondestructive testing of advanced ceramic materials by infrared thermography and holographic interferometry[C]//Proceedings of SPIE 7661,Thermosense XXXII.Orlando,Florida:[s.n.],2010:200-209.
    [55]
    EMAM S M,SAYYEDBARZANI S A.Dimensional deviation measurement of ceramic tiles according to ISO 10545-2 using the machine vision[J].The International Journal of Advanced Manufacturing Technology,2019,100(5/6/7/8):1405-1418.
    [56]
    LI X L,ZENG S G,ZHENG S,et al.Surface crack detection of ceramic tile based on sliding filter and automatic region growth[J].Laser & Optoelectronics Progress,2019,56(21):211003.
    [57]
    KO ARǦ ENSKÁ M,MANYCHOVÁ M.New possibilities of non-destructive testing of ceramic specimen integrity[J].Ceramics-Silikáty,2010,54(1):72-77.
    [58]
    TSAI T H,JEYAPRAKASH N,YANG C H.Non-destructive evaluations of 3D printed ceramic teeth:Young's modulus and defect detections[J].Ceramics International,2020,46(14):22987-22998.
    [59]
    ZHANG K Q,MENG Q Y,CAI N J,et al.Effects of solid loading on stereolithographic additive manufactured ZrO2 ceramic:A quantitative defect study by X-ray computed tomography[J].Ceramics International,2021,47(17):24353-24359.
    [60]
    QIAN L H,CUI X N,LIU S A,et al.Image-based numerical simulation of the local cyclic deformation behavior around cast pore in steel[J].Materials Science and Engineering:A,2016,678:347-354.
    [61]
    PLESSIS A D,YADROITSAVA I,ROUX S G L,et al.Prediction of mechanical performance of Ti6Al4V cast alloy based on microCT-based load simulation[J].Journal of Alloys and Compounds,2017,724:267-274.

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