F. Arroyo Torralvo , F. Alvarez-Martin , N. Moreno Bermejo , Y. Luna Galiano , C. Leiva , L.F. Vilches
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Metals were eluted from the resins using another real effluent (primary raffinate, effluent from the primary solvent extraction) from the same plant.</p><p>Experiments for the uptake and elution were carried out in batch and in columns. The effect of pH, resin dosing, and temperature onto metals retention are analyzed. Retention efficiencies (loading capacities) were 50.1% (8.1<!--> <!-->mg·g<sup>−<!--> <!-->1</sup>) for Cu and 54.8% (23.2<!--> <!-->mg·g<sup>−<!--> <!-->1</sup>) for Fe<sup>3<!--> <!-->+</sup> under the optimal operational conditions (pH<!--> <!-->=<!--> <!-->0.45 and <em>T</em> <!-->=<!--> <!-->65<!--> <!-->°C). These values were confirmed in column tests. It is possible to recover Fe<sup>3<!--> <!-->+</sup> and Cu from the secondary raffinate, leaving most of Fe<sup>2<!--> <!-->+</sup> and other elements in solution. The experimental affinities that TP207 showed are: Cu<!--> <!-->><!--> <!-->Fe<sup>3<!--> <!-->+</sup> <!-->><!--> <!-->Fe<sup>2<!--> <!-->+</sup> <!-->><!--> <!-->Zn.</p><p>The elution of Fe and Cu was quantitatively achieved with concentrated H<sub>2</sub>SO<sub>4</sub> solution. When acidified primary raffinate was used as eluting solution, an enriched solution containing 14.3<!--> <!-->g Cu·L<sup>−<!--> <!-->1</sup>, 20.3<!--> <!-->g Fe<sup>2<!--> <!-->+</sup>·L<sup>−<!--> <!-->1</sup>, and 18.6 de g Fe<sup>3<!--> <!-->+</sup>·L<sup>−<!--> <!-->1</sup> was obtained. This enriched primary raffinate can be reintroduced in the process as leaching solution.</p><p>So, after the modification of the process, using secondary raffinate as loading solution and acidified primary raffinate as eluting solution, the ion-exchange stage could substitute the external FeSO<sub>4</sub> addition. In addition, 30–80<!--> <!-->kg<!--> <!-->Cu·h<sup>−<!--> <!-->1</sup> are reintroduced in the process.</p></div>","PeriodicalId":14022,"journal":{"name":"International Journal of Mineral Processing","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2017-12-10","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://sci-hub-pdf.com/10.1016/j.minpro.2017.10.006","citationCount":"4","resultStr":"{\"title\":\"Effluent valorization in copper hydrometallurgy plant\",\"authors\":\"F. Arroyo Torralvo , F. Alvarez-Martin , N. Moreno Bermejo , Y. Luna Galiano , C. Leiva , L.F. Vilches\",\"doi\":\"10.1016/j.minpro.2017.10.006\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>Copper is commonly produced by hydrometallurgical processes. The production of this metal results in the formation of emissions (unwanted solids, liquids and gases). In this paper, an effluent from a Cu producer company is valorized by means of Fe and Cu recovery.</p><p><span>In the current process, an effluent from the secondary solvent extraction (secondary raffinate) was sent to neutralization plant to be discharged. In this paper a modification of the process is proposed. The secondary raffinate was contacted with TP207 resin for Fe</span><sup>3<!--> <!-->+</sup> and Cu recovery. Metals were eluted from the resins using another real effluent (primary raffinate, effluent from the primary solvent extraction) from the same plant.</p><p>Experiments for the uptake and elution were carried out in batch and in columns. The effect of pH, resin dosing, and temperature onto metals retention are analyzed. Retention efficiencies (loading capacities) were 50.1% (8.1<!--> <!-->mg·g<sup>−<!--> <!-->1</sup>) for Cu and 54.8% (23.2<!--> <!-->mg·g<sup>−<!--> <!-->1</sup>) for Fe<sup>3<!--> <!-->+</sup> under the optimal operational conditions (pH<!--> <!-->=<!--> <!-->0.45 and <em>T</em> <!-->=<!--> <!-->65<!--> <!-->°C). These values were confirmed in column tests. It is possible to recover Fe<sup>3<!--> <!-->+</sup> and Cu from the secondary raffinate, leaving most of Fe<sup>2<!--> <!-->+</sup> and other elements in solution. The experimental affinities that TP207 showed are: Cu<!--> <!-->><!--> <!-->Fe<sup>3<!--> <!-->+</sup> <!-->><!--> <!-->Fe<sup>2<!--> <!-->+</sup> <!-->><!--> <!-->Zn.</p><p>The elution of Fe and Cu was quantitatively achieved with concentrated H<sub>2</sub>SO<sub>4</sub> solution. 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引用次数: 4
摘要
铜通常用湿法冶金法生产。这种金属的生产导致排放物的形成(不需要的固体、液体和气体)。以某铜生产企业为研究对象,采用回收铁、铜的方法对废水进行了酸化处理。本工艺将二次溶剂萃取出水(二次萃余液)送入中和厂排放。本文对该工艺进行了改进。二次萃余液与TP207树脂接触,回收Fe3 +和Cu。使用同一工厂的另一种实际流出物(一次萃余液,一次溶剂萃取流出物)从树脂中洗脱金属。采用间歇式和柱式进行了吸附和洗脱实验。分析了pH值、树脂投加量和温度对金属保留率的影响。在最佳操作条件(pH = 0.45, T = 65℃)下,Cu和Fe3 +的保留率分别为50.1% (8.1 mg·g−1)和54.8% (23.2 mg·g−1)。这些值已在列试验中得到确认。从二次萃余液中可以回收Fe3 +和Cu,大部分Fe2 +和其他元素留在溶液中。TP207的实验亲和力为:Cu >Fe3 + >Fe2 + >锌。用浓硫酸溶液定量洗脱铁和铜。以酸化后的原生萃余液为洗脱液,可得到含14.3 g Cu·L−1、20.3 g Fe2 +·L−1和18.6 g Fe3 +·L−1的富集溶液。这种富集的原生萃余液可以作为浸出液重新引入工艺中。因此,在对工艺进行改造后,以二次萃余液为加载液,酸化一次萃余液为洗脱液,离子交换阶段可以代替外部添加FeSO4。此外,该工艺还重新引入了30 ~ 80 kg Cu·h−1。
Effluent valorization in copper hydrometallurgy plant
Copper is commonly produced by hydrometallurgical processes. The production of this metal results in the formation of emissions (unwanted solids, liquids and gases). In this paper, an effluent from a Cu producer company is valorized by means of Fe and Cu recovery.
In the current process, an effluent from the secondary solvent extraction (secondary raffinate) was sent to neutralization plant to be discharged. In this paper a modification of the process is proposed. The secondary raffinate was contacted with TP207 resin for Fe3 + and Cu recovery. Metals were eluted from the resins using another real effluent (primary raffinate, effluent from the primary solvent extraction) from the same plant.
Experiments for the uptake and elution were carried out in batch and in columns. The effect of pH, resin dosing, and temperature onto metals retention are analyzed. Retention efficiencies (loading capacities) were 50.1% (8.1 mg·g− 1) for Cu and 54.8% (23.2 mg·g− 1) for Fe3 + under the optimal operational conditions (pH = 0.45 and T = 65 °C). These values were confirmed in column tests. It is possible to recover Fe3 + and Cu from the secondary raffinate, leaving most of Fe2 + and other elements in solution. The experimental affinities that TP207 showed are: Cu > Fe3 + > Fe2 + > Zn.
The elution of Fe and Cu was quantitatively achieved with concentrated H2SO4 solution. When acidified primary raffinate was used as eluting solution, an enriched solution containing 14.3 g Cu·L− 1, 20.3 g Fe2 +·L− 1, and 18.6 de g Fe3 +·L− 1 was obtained. This enriched primary raffinate can be reintroduced in the process as leaching solution.
So, after the modification of the process, using secondary raffinate as loading solution and acidified primary raffinate as eluting solution, the ion-exchange stage could substitute the external FeSO4 addition. In addition, 30–80 kg Cu·h− 1 are reintroduced in the process.
期刊介绍:
International Journal of Mineral Processing has been discontinued as of the end of 2017, due to the merger with Minerals Engineering.
The International Journal of Mineral Processing covers aspects of the processing of mineral resources such as: Metallic and non-metallic ores, coals, and secondary resources. Topics dealt with include: Geometallurgy, comminution, sizing, classification (in air and water), gravity concentration, flotation, electric and magnetic separation, thickening, filtering, drying, and (bio)hydrometallurgy (when applied to low-grade raw materials), control and automation, waste treatment and disposal. In addition to research papers, the journal publishes review articles, technical notes, and letters to the editor..
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