中国有色金属学报
中國有色金屬學報
중국유색금속학보
THE CHINESE JOURNAL OF NONFERROUS METALS
2015年
4期
866-874
,共9页
孙擎擎%董朋轩%孙睿吉%陈启元%陈康华
孫擎擎%董朋軒%孫睿吉%陳啟元%陳康華
손경경%동붕헌%손예길%진계원%진강화
Al-6.2Zn-2.3Mg-2.3Cu铝合金%时效制度%电化学腐蚀%腐蚀形貌
Al-6.2Zn-2.3Mg-2.3Cu鋁閤金%時效製度%電化學腐蝕%腐蝕形貌
Al-6.2Zn-2.3Mg-2.3Cu려합금%시효제도%전화학부식%부식형모
Al-6.2Zn-2.3Mg-2.3Cu alloy%ageing process%electrochemical corrosion%corrosion morphology
采用开路电位、循环极化曲线、电化学阻抗谱及腐蚀形貌表征等研究不同时效制度下 Al-6.2Zn-2.3Mg-2.3Cu铝合金分别在3.5%NaCl(质量分数)以及10 mmol/L NaCl+0.1mol/L Na2SO4溶液中的电化学腐蚀行为。结果表明:4种时效制度处理后,挤压铝合金耐局部腐蚀能力由大到小的顺序依次为 T76+T6、T76、T77、T6。试样在10 mmol/L NaCl+0.1mol/L Na2SO4溶液中主要发生点蚀,从循环阳极极化曲线上可以观察到明显的点蚀电位和点蚀转换电位;在3.5%NaCl 溶液中发生点蚀和晶间腐蚀。利用点蚀电位φb以及点蚀电位与自腐蚀电位的差值(φb?φcorr)表征局部腐蚀发生的难易程度,自腐蚀电位和再钝化电位的差值(φcorr?φrep)表征局部腐蚀的发展程度。另外,表征了试样的硬度和导电率等性能,发现与峰时效相比,三级时效处理后的合金的硬度并无显著降低,且T76+T6态的硬度稍大于T77态的。可见扩大三级时效的回归时间窗口、降低回归温度,可使合金同时获得更优异的强度和耐蚀性能。
採用開路電位、循環極化麯線、電化學阻抗譜及腐蝕形貌錶徵等研究不同時效製度下 Al-6.2Zn-2.3Mg-2.3Cu鋁閤金分彆在3.5%NaCl(質量分數)以及10 mmol/L NaCl+0.1mol/L Na2SO4溶液中的電化學腐蝕行為。結果錶明:4種時效製度處理後,擠壓鋁閤金耐跼部腐蝕能力由大到小的順序依次為 T76+T6、T76、T77、T6。試樣在10 mmol/L NaCl+0.1mol/L Na2SO4溶液中主要髮生點蝕,從循環暘極極化麯線上可以觀察到明顯的點蝕電位和點蝕轉換電位;在3.5%NaCl 溶液中髮生點蝕和晶間腐蝕。利用點蝕電位φb以及點蝕電位與自腐蝕電位的差值(φb?φcorr)錶徵跼部腐蝕髮生的難易程度,自腐蝕電位和再鈍化電位的差值(φcorr?φrep)錶徵跼部腐蝕的髮展程度。另外,錶徵瞭試樣的硬度和導電率等性能,髮現與峰時效相比,三級時效處理後的閤金的硬度併無顯著降低,且T76+T6態的硬度稍大于T77態的。可見擴大三級時效的迴歸時間窗口、降低迴歸溫度,可使閤金同時穫得更優異的彊度和耐蝕性能。
채용개로전위、순배겁화곡선、전화학조항보급부식형모표정등연구불동시효제도하 Al-6.2Zn-2.3Mg-2.3Cu려합금분별재3.5%NaCl(질량분수)이급10 mmol/L NaCl+0.1mol/L Na2SO4용액중적전화학부식행위。결과표명:4충시효제도처리후,제압려합금내국부부식능력유대도소적순서의차위 T76+T6、T76、T77、T6。시양재10 mmol/L NaCl+0.1mol/L Na2SO4용액중주요발생점식,종순배양겁겁화곡선상가이관찰도명현적점식전위화점식전환전위;재3.5%NaCl 용액중발생점식화정간부식。이용점식전위φb이급점식전위여자부식전위적차치(φb?φcorr)표정국부부식발생적난역정도,자부식전위화재둔화전위적차치(φcorr?φrep)표정국부부식적발전정도。령외,표정료시양적경도화도전솔등성능,발현여봉시효상비,삼급시효처리후적합금적경도병무현저강저,차T76+T6태적경도초대우T77태적。가견확대삼급시효적회귀시간창구、강저회귀온도,가사합금동시획득경우이적강도화내식성능。
The electrochemical corrosion behavior of extruded Al-6.2Zn-2.3Mg-2.3Cu Al alloy was investigated. The open circuit potential (OCP), cyclic polarization curve and electrochemical impedance spectroscopy (EIS) were performed in 3.5% (mass fraction) NaCl and 10 mmol/L NaCl+0.1 mol/L Na2SO4 solutions. The results show that the resistance to localized corrosion of various ageing processes according to decreasing order is T76+T6, T76, T77, T6, as deduced from electrochemical parameters, such as OCP, corrosion potential, repassivation potential, pitting potential, pitting transition potential, linear polarization resistance, corrosion current density and charge transfer resistance of EIS. Corrosion morphologies indicate that pitting corrosion is the main corrosion form for Al-6.2Zn-2.3Mg-2.3Cu alloy in the solution of 10 mmol/L NaCl+0.1 mol/L Na2SO4, which can be terrified by the occurrence of pitting potential and pitting transition potential in its cyclic polarization curves. Being different from 10 mmol/L NaCl+0.1 mol/L Na2SO4, the pitting corrosion and intergranular corrosion (IGC) can be observed in 3.5%NaCl solution.φb, (φb?φcorr), and (φcorr?φrep) were used as criteria to evaluate the localized corrosion. Additionally, the influence of ageing process on the hardness and conductivity was also discussed. T76+T6 shows the least decline of hardness comparing to T6 and the best corrosive resistance amongst the four ageing processes.
