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
6期
1739-1745
,共7页
朱晓光%席晓丽%聂祚仁%马立文%朱健健
硃曉光%席曉麗%聶祚仁%馬立文%硃健健
주효광%석효려%섭조인%마립문%주건건
金%甲基异丁酮%析因设计%废印刷线路板%萃取率%响应面法
金%甲基異丁酮%析因設計%廢印刷線路闆%萃取率%響應麵法
금%갑기이정동%석인설계%폐인쇄선로판%췌취솔%향응면법
Au%methyl isobutyl ketone%factorial design%waste printed circuit board%extraction rate%respone surface methodology
对回收废线路板采用“破碎—氧化硫酸法分离贱金属—浸出金—甲基异丁酮溶剂萃取提金—反萃析金”工艺获得海绵金,采用统计学方法及Minitab15软件对甲基异丁酮(MIBK)萃取线路板中金的影响因素进行探讨和分析。针对萃金过程,首先采用析因设计法进行5因素2水平的部分析因试验设计,对MIBK萃金的影响因素进行筛选,发现相比、反应时间和反应温度对金萃取率有显著影响,而且相比时间的影响具有正效应,温度具有负效应;利用Box-Behnken中心组合设计及响应面分析对影响金萃取率的显著因素做进一步的优化,建立多元二次回归方程拟合模型,得到最佳的萃取条件:相比0.34,反应时间12.4 min,反应温度28℃,在此条件下金的萃取率可高达96.1%,对MIBK萃金后的有机相用5%的草酸溶液进行反萃还原,得到海绵金。
對迴收廢線路闆採用“破碎—氧化硫痠法分離賤金屬—浸齣金—甲基異丁酮溶劑萃取提金—反萃析金”工藝穫得海綿金,採用統計學方法及Minitab15軟件對甲基異丁酮(MIBK)萃取線路闆中金的影響因素進行探討和分析。針對萃金過程,首先採用析因設計法進行5因素2水平的部分析因試驗設計,對MIBK萃金的影響因素進行篩選,髮現相比、反應時間和反應溫度對金萃取率有顯著影響,而且相比時間的影響具有正效應,溫度具有負效應;利用Box-Behnken中心組閤設計及響應麵分析對影響金萃取率的顯著因素做進一步的優化,建立多元二次迴歸方程擬閤模型,得到最佳的萃取條件:相比0.34,反應時間12.4 min,反應溫度28℃,在此條件下金的萃取率可高達96.1%,對MIBK萃金後的有機相用5%的草痠溶液進行反萃還原,得到海綿金。
대회수폐선로판채용“파쇄—양화류산법분리천금속—침출금—갑기이정동용제췌취제금—반췌석금”공예획득해면금,채용통계학방법급Minitab15연건대갑기이정동(MIBK)췌취선로판중금적영향인소진행탐토화분석。침대췌금과정,수선채용석인설계법진행5인소2수평적부분석인시험설계,대MIBK췌금적영향인소진행사선,발현상비、반응시간화반응온도대금췌취솔유현저영향,이차상비시간적영향구유정효응,온도구유부효응;이용Box-Behnken중심조합설계급향응면분석대영향금췌취솔적현저인소주진일보적우화,건립다원이차회귀방정의합모형,득도최가적췌취조건:상비0.34,반응시간12.4 min,반응온도28℃,재차조건하금적췌취솔가고체96.1%,대MIBK췌금후적유궤상용5%적초산용액진행반췌환원,득도해면금。
The sponge gold was obtained by using“breaking—removing low priced metal with sulfuric acid oxidation method—leaching gold—extracting gold with methyl isobutyl ketone (MIBK)—stripping gold”process. The statistical methods were used to analyze the impact of different factors on the extraction of Au (Ⅲ) using MIBK as extractant. The factorial designs with five factors and two levels were firstly used to evaluate the relative effects that might affect the extraction of gold from the waste printed circuit board with MIBK. The results show that the factors including the phase ratio of organic and aqueous, the reaction time and the temperature, have significant impacts on the extraction rate of gold. The phase ratio and reaction time have positive impacts on the gold extraction, while temperature has negative impact. Based on this, Box-Behnken central composite design combining with response surface methodology (RSM) was employed to optimize the most important affecting factors of the extraction rate. The optimum conditions for the extraction are the organic and aqueous phase ratio of 0.34, reaction time of 12.4 min and temperature of 28℃, which are calculated from an established quadratic equation of one variable regression model. Under the optimized conditions, the gold extraction rate can reach as high as 96.1%. At last, the organic phase is stripped with solution of oxalic acid (5%) to get sponge gold.