化工学报
化工學報
화공학보
JOURNAL OF CHEMICAL INDUSY AND ENGINEERING (CHINA)
2014年
2期
633-640
,共8页
陶绍虎%狄跃忠%彭建平%王耀武%赵坤%冯乃祥
陶紹虎%狄躍忠%彭建平%王耀武%趙坤%馮迺祥
도소호%적약충%팽건평%왕요무%조곤%풍내상
LiF%铝电解%阴极电化学%循环伏安%铝钨金属间化合物
LiF%鋁電解%陰極電化學%循環伏安%鋁鎢金屬間化閤物
LiF%려전해%음겁전화학%순배복안%려오금속간화합물
LiF%aluminum electrolysis%cathodic electrochemistry%cyclic voltammetry%Al-Wintermetallic compound
电解铝工业中铝在阴极上析出,铝析出反应的机理对电解铝生产具有理论指导意义。在运用循环伏安法研究的基础上,通过理论计算,对Na3AlF6-Al2O3和Na3AlF6-Al2O3-LiF体系中金属铝在钨电极上的电化学沉积行为以及铝钨金属间化合物的形成机理进行了研究。结果表明:两体系中铝钨金属间化合物在50 mV·s-1≤ν≤150 mV·s-1扫描速率下的形成过程是受扩散控制的准可逆过程。在化合物形成的过程中,两体系中Al3+的扩散系数从4.54×10-9 cm2·s-1增长到5.71×10-9 cm2·s-1,Al3+反应的活化能分别为11.14 kJ·mol-1和10.47 kJ·mol-1。在Na3AlF6-Al2O3-LiF体系的还原过程中,Li并没有还原析出,而在氧化过程中Al在金属间化合物中的氧化电流增大;在恒电流电解时,Al-W金属间化合物并不溶于熔盐中,会附着在工作电极表面,LiF的加入会使电极表面的WAl4量变小,取而代之的是Al2O3的增加,说明LiF的加入使电解更加稳定,抑制了电极表面WAl4的生长。
電解鋁工業中鋁在陰極上析齣,鋁析齣反應的機理對電解鋁生產具有理論指導意義。在運用循環伏安法研究的基礎上,通過理論計算,對Na3AlF6-Al2O3和Na3AlF6-Al2O3-LiF體繫中金屬鋁在鎢電極上的電化學沉積行為以及鋁鎢金屬間化閤物的形成機理進行瞭研究。結果錶明:兩體繫中鋁鎢金屬間化閤物在50 mV·s-1≤ν≤150 mV·s-1掃描速率下的形成過程是受擴散控製的準可逆過程。在化閤物形成的過程中,兩體繫中Al3+的擴散繫數從4.54×10-9 cm2·s-1增長到5.71×10-9 cm2·s-1,Al3+反應的活化能分彆為11.14 kJ·mol-1和10.47 kJ·mol-1。在Na3AlF6-Al2O3-LiF體繫的還原過程中,Li併沒有還原析齣,而在氧化過程中Al在金屬間化閤物中的氧化電流增大;在恆電流電解時,Al-W金屬間化閤物併不溶于鎔鹽中,會附著在工作電極錶麵,LiF的加入會使電極錶麵的WAl4量變小,取而代之的是Al2O3的增加,說明LiF的加入使電解更加穩定,抑製瞭電極錶麵WAl4的生長。
전해려공업중려재음겁상석출,려석출반응적궤리대전해려생산구유이론지도의의。재운용순배복안법연구적기출상,통과이론계산,대Na3AlF6-Al2O3화Na3AlF6-Al2O3-LiF체계중금속려재오전겁상적전화학침적행위이급려오금속간화합물적형성궤리진행료연구。결과표명:량체계중려오금속간화합물재50 mV·s-1≤ν≤150 mV·s-1소묘속솔하적형성과정시수확산공제적준가역과정。재화합물형성적과정중,량체계중Al3+적확산계수종4.54×10-9 cm2·s-1증장도5.71×10-9 cm2·s-1,Al3+반응적활화능분별위11.14 kJ·mol-1화10.47 kJ·mol-1。재Na3AlF6-Al2O3-LiF체계적환원과정중,Li병몰유환원석출,이재양화과정중Al재금속간화합물중적양화전류증대;재항전류전해시,Al-W금속간화합물병불용우용염중,회부착재공작전겁표면,LiF적가입회사전겁표면적WAl4량변소,취이대지적시Al2O3적증가,설명LiF적가입사전해경가은정,억제료전겁표면WAl4적생장。
Electrochemical reactions of Al3+and formation mechanism of Al-W intermetallic compound on tungsten electrode were investigated by means of cyclic voltammetry and theoretical calculation analysis. Al3+was reduced to Al metal in a single step and the deposition potential of sodium was more negative than aluminum in molten cryolite system. In both Na3AlF6-Al2O3 system and Na3AlF6-Al2O3-LiF system, the deposition reaction of Al3+ as Al-W intermetallic compounds on tungsten electrode was quasi-reversible, involving diffusion process from the sweep rate range of 50 mV·s-1 to 150 mV·s-1. During the forming process of Al-W intermetallic compound, Al3+ diffusion coefficient increased from 4.54×10-9 cm2·s-1 to 5.71×10-9 cm2·s-1, and reaction activation energy decreased from 11.14 kJ·mol-1 to 10.47 kJ·mol-1. Al-W intermetallic compound was insoluble in both Na3AlF6-Al2O3 system and Na3AlF6-Al2O3-LiF system. In Na3AlF6-Al2O3-LiF system, Li did not deposit out on tungsten electrode during the reduction process and oxidation current was larger than that in Na3AlF6-Al2O3 system during the formation process of Al-W intermetallic compound. In the constant current electrolysis experiment, XRD, SEM, EDS showed that Al-W intermetallic compound was insoluble in molten salt, but adhered to the surface of the working electrode. Adding LiF decreased Al-W intermetallic compound (WAl4) quantity but increased Al2O3 quantity. With the formation of Al-W intermetallic compound, Li-Al intermetallic compound also formed at the same time and it was soluble in Na3AlF6-Al2O3-LiF system. It confirmed that the working electrode was more stable during the electrolysis process after adding LiF. LiF inhibited the growth of WAl4 and increased the activity of Al3+in Na3AlF6-Al2O3-LiF system. As the cathode of aluminum electrolysis, alloying effect was obvious on tungsten electrode during the electrolysis process. In order to guarantee normal electrolysis, tungsten wire electrode should be pretreated to form a stable alloy.