中国有色金属学报
中國有色金屬學報
중국유색금속학보
THE CHINESE JOURNAL OF NONFERROUS METALS
2013年
7期
1892-1899
,共8页
高英俊%罗志荣%黄礼琳%林葵
高英俊%囉誌榮%黃禮琳%林葵
고영준%라지영%황례림%림규
晶体相场模型%微裂纹扩展%应变%韧性材料
晶體相場模型%微裂紋擴展%應變%韌性材料
정체상장모형%미렬문확전%응변%인성재료
phase-field-crystal model%microcrack propagation%strain%ductile materials
采用晶体相场模型研究韧性单晶材料在双轴拉伸条件下微裂纹扩展和连通的演化过程,分析应变、初始裂口处原子密度等因素对裂纹扩展和分叉的影响。结果表明:初始裂口处原子密度对裂纹扩展有明显的影响;对于双轴拉伸作用,当应变较小时,裂纹扩展不分叉;当应变较大时,裂纹扩展才能出现分叉。在裂纹扩展过程中,体系能量不断降低;当裂纹出现分叉时,体系能量降低更快,这表明裂纹扩展过程中弹性应变能的释放比表面能的增加要快。裂纹在扩展过程中,在分叉处会出现与主裂纹断开的孤立的微小空洞。这些微小空洞将成为新的裂纹萌生之地,它们在应力的作用下不断长大,连成一线,形成新的裂纹分支。同一条直线上的两条初始裂纹在扩展过程中,当裂纹尖端靠近时,尖端相互吸引,裂纹相互连通。本研究所得结果与相关模拟结果和实验结果吻合。
採用晶體相場模型研究韌性單晶材料在雙軸拉伸條件下微裂紋擴展和連通的縯化過程,分析應變、初始裂口處原子密度等因素對裂紋擴展和分扠的影響。結果錶明:初始裂口處原子密度對裂紋擴展有明顯的影響;對于雙軸拉伸作用,噹應變較小時,裂紋擴展不分扠;噹應變較大時,裂紋擴展纔能齣現分扠。在裂紋擴展過程中,體繫能量不斷降低;噹裂紋齣現分扠時,體繫能量降低更快,這錶明裂紋擴展過程中彈性應變能的釋放比錶麵能的增加要快。裂紋在擴展過程中,在分扠處會齣現與主裂紋斷開的孤立的微小空洞。這些微小空洞將成為新的裂紋萌生之地,它們在應力的作用下不斷長大,連成一線,形成新的裂紋分支。同一條直線上的兩條初始裂紋在擴展過程中,噹裂紋尖耑靠近時,尖耑相互吸引,裂紋相互連通。本研究所得結果與相關模擬結果和實驗結果吻閤。
채용정체상장모형연구인성단정재료재쌍축랍신조건하미렬문확전화련통적연화과정,분석응변、초시렬구처원자밀도등인소대렬문확전화분차적영향。결과표명:초시렬구처원자밀도대렬문확전유명현적영향;대우쌍축랍신작용,당응변교소시,렬문확전불분차;당응변교대시,렬문확전재능출현분차。재렬문확전과정중,체계능량불단강저;당렬문출현분차시,체계능량강저경쾌,저표명렬문확전과정중탄성응변능적석방비표면능적증가요쾌。렬문재확전과정중,재분차처회출현여주렬문단개적고립적미소공동。저사미소공동장성위신적렬문맹생지지,타문재응력적작용하불단장대,련성일선,형성신적렬문분지。동일조직선상적량조초시렬문재확전과정중,당렬문첨단고근시,첨단상호흡인,렬문상호련통。본연구소득결과여상관모의결과화실험결과문합。
The morphology evolution of microcrack propagation and connecting in ductile single crystal materials under the biaxial tensile deformation were simulated by the phase-field-crystal model. The effects of the factors such as the stain, the atomic density in initial crack notch on crack propagation were analyzed. The simulation results show that the atomic density in the crack notch has an effect on crack propagation. As the tensile strain exerting on the monocrystalline sample by biaxial tensile, the crack propagation cannot branch at small strain, the first-branching and second-branching occur during crack propagation when the strain is great enough. It is observed that system energy decreases over time and the energy decreases faster during crack branching. It indicates that the decrease in elastic strain energy is larger than the increase in surface energy during crack propagation. A string of isolate cavities near main cracks can be seen and these cavities will become new cracks with time lasting during crack propagation. They will continue to grow up along a line and become a new branch crack under the stress. The tips of two initial cracks on the same line would attract each other during crack propagation, once they made the connection, the two cracks would form into one. The simulation results are in agreement with other simulation results and experimental ones.