表面技术
錶麵技術
표면기술
SURFACE TECHNOLOGY
2014年
6期
48-52
,共5页
X80管线钢%氢致开裂(HIC)%酸性环境
X80管線鋼%氫緻開裂(HIC)%痠性環境
X80관선강%경치개렬(HIC)%산성배경
X80 pipeline steel%hydrogen induced cracking%acidic environment
目的研究X80管线钢在我国典型酸性环境(鹰潭土壤模拟溶液)下的氢致开裂行为。方法采用电化学动电位扫描技术、慢应变速率拉伸实验和扫描电镜技术,分析氢在X80管线钢中的渗透行为、材料的放氢行为、电化学充氢对材料拉伸性能的影响以及材料断口的形貌。结果通过氢渗透实验测得,在室温下,氢在X80管线钢中的的氢扩散通量J肄=7.31×10-11 mol/(cm2·s),有效扩散系数Def =5.36×10-8 cm2/s,可扩散氢浓度C0=7.64×10-5 mol/cm3。钢中的氧化铝类非金属夹杂及表面点蚀坑促进了氢致裂纹的萌生,充氢后试样发生穿晶断裂。随着充氢时间的增加,断口由韧性断裂转变为脆性断裂,氢致开裂敏感性增高。结论X80管线钢在我国典型酸性环境下(鹰潭土壤模拟溶液)具有较高的氢致开裂敏感性。
目的研究X80管線鋼在我國典型痠性環境(鷹潭土壤模擬溶液)下的氫緻開裂行為。方法採用電化學動電位掃描技術、慢應變速率拉伸實驗和掃描電鏡技術,分析氫在X80管線鋼中的滲透行為、材料的放氫行為、電化學充氫對材料拉伸性能的影響以及材料斷口的形貌。結果通過氫滲透實驗測得,在室溫下,氫在X80管線鋼中的的氫擴散通量J肄=7.31×10-11 mol/(cm2·s),有效擴散繫數Def =5.36×10-8 cm2/s,可擴散氫濃度C0=7.64×10-5 mol/cm3。鋼中的氧化鋁類非金屬夾雜及錶麵點蝕坑促進瞭氫緻裂紋的萌生,充氫後試樣髮生穿晶斷裂。隨著充氫時間的增加,斷口由韌性斷裂轉變為脆性斷裂,氫緻開裂敏感性增高。結論X80管線鋼在我國典型痠性環境下(鷹潭土壤模擬溶液)具有較高的氫緻開裂敏感性。
목적연구X80관선강재아국전형산성배경(응담토양모의용액)하적경치개렬행위。방법채용전화학동전위소묘기술、만응변속솔랍신실험화소묘전경기술,분석경재X80관선강중적삼투행위、재료적방경행위、전화학충경대재료랍신성능적영향이급재료단구적형모。결과통과경삼투실험측득,재실온하,경재X80관선강중적적경확산통량J이=7.31×10-11 mol/(cm2·s),유효확산계수Def =5.36×10-8 cm2/s,가확산경농도C0=7.64×10-5 mol/cm3。강중적양화려류비금속협잡급표면점식갱촉진료경치렬문적맹생,충경후시양발생천정단렬。수착충경시간적증가,단구유인성단렬전변위취성단렬,경치개렬민감성증고。결론X80관선강재아국전형산성배경하(응담토양모의용액)구유교고적경치개렬민감성。
ABSTRACT:Objective To investigate the hydrogen induced cracking ( HIC) behavior of X80 pipeline steel in the typical acidic environment (simulated solutions of the acidic soil in Yingtan). Methods Using the potentiodynamic polarization curves, slow strain rate test ( SSRT) and SEM technology, the behavior of hydrogen permeation, the behavior of hydrogen release, the influence of tensile properties after hydrogen charging and the fracture morphology were analyzed. Results According to the result of hydrogen permeation test, the hydrogen diffusion flux at room temperature was 7. 31í10-11 mol/(cm2·s), the effective diffusivity of hydro-gen was 5. 36í10-8 cm2/s and the diffusible hydrogen concentration was 7. 64í10-5 mol/cm3 . Moreover, the alumina nonmetallic inclusions and surface pitting promoted the initiation hydrogen induced crack, and the failure mode was transgranular cracking after hydrogen charging. With the increase of hydrogen charging time, the fracture morphology changed from ductile fracture to brittle fracture, and the sensitivity to HIC increased. Conclusion X80 pipeline steel had high sensitivity to HIC in the typical acidic envi-ronment ( simulated solutions of the acidic soil in Yingtan) .