The relationship between Charpy absorbed energy and the fracture toughness by means of the (crack tip opening displacement (CTOD)) method was analyzed based on the Weibull stress criterion. The Charpy absorbed energy and the fracture toughness were measured for the SN490B steel under the ductile-brittle transition temperature region. For the instrumented Charpy impact test, the curves between the loading point displacement and the load against time were recorded. The critical Weibull stress was taken as a fracture controlled parameter, and it could not be affected by the specimen configuration and the loading pattern based on the local approach. The parameters controlled brittle fracture are obtained from the Charpy absorbed energy results, then the fracture toughness for the compact tension (CT) specimen is predicted. It is found that the results predicted are in good agreement with the experimental. The fracture toughness could be evaluated by the Charpy absorbed energy, because the local approach gives a good description for the brittle fracture even though the Charpy impact specimen or the CT specimen is used for the given material.
参考文献
| [1] | SChaudhuri,SOjha:J .[M].Pressure Vessels and Piping,1986,29:23. |
| [2] | IOda .[J].Engineering Fracture Mechanics,1988,29:663. |
| [3] | JDHarrson .[J].Metal Construction,1980,12:415. |
| [4] | TNakamura,CFShih .[J].Engineering Fracture Mechanics,1986,25:323. |
| [5] | PKLiaw,JDL,es .[J].Metallurgical and Materials Transactions A:Physical Metallurgy and Materials Science,1986,17:473. |
| [6] | FMinami;MOhata MToyoda .[J].Journal of the Society of Naval Architects of Japan,1997,182:647. |
| [7] | PVargas,RHDoddsJr .[J].ASTM STP,1995,1256:715. |
| [8] | KDuane .[J].Engineering Structures,1998,20:249. |
| [9] | PEgor .[J].Engineering Structures,1998,20:1030. |
| [10] | RHDoddsJr;TL erson;MTKirk .[J].International Journal of Fracture,1991,53:1. |
| [11] | YYWang JRGordon.Proceeding Shallow Crack Fracture Mechanics Toughness Tests Applications[M].Cambridge,1992 |
| [12] | KHSchwale .[J].ASTM STP,1995,6:763. |
| [13] | FMinami;MOhata MToyoda.[C].in Proc 15th ConfOMAE Florence,1996:193. |
| [14] | FMeremin .[J].Metallurgical and Materials Transactions A:Physical Metallurgy and Materials Science,1983,14:2277. |
| [15] | FMudry .[J].Nuclear Engineering and Design,1987,105:65. |
| [16] | Hongyang JING,Lianyong XU,Lixing HUO,Yufeng ZHANG.Evaluation on Fracture Toughness at Dynamic Loading for Welded Joint Based on the Local Approach[J].材料科学技术学报(英文版),2004(01):113-117. |
| [17] | HYJing;LXHuo;YFZhang .[J].Journal of Materials Science and Technology,1999,15:567. |
| [18] | FMinami;DMunz . BTrolldenier .[J].International Journal of Fracture,1992,54:197. |
| [19] | LXia CFShih .[J].Journal of the Mechanics and Physics of Solids,1995,43:233. |
| [20] | LXia CFShih .[J].Journal of the Mechanics and Physics of Solids,1996,44:603. |
| [21] | ritishstandard.Fracture Mechanics Toughness Tests Method for Determination KIC, Critical CTOD and Critical J[J].Values of Metallic Materials BS7448(Part Ⅰ),1991 |
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