Mahiroglu Ayse, Tarlan-Yel Esra, Sevimli Mehmet Faik
Selcuk University, Environmental Engineering Department, 42075 Campus, Konya, Turkey.
J Hazard Mater. 2009 Jul 30;166(2-3):782-7. doi: 10.1016/j.jhazmat.2008.11.119. Epub 2008 Dec 6.
The treatability of a copper mine wastewater, including heavy metals, AMD, as well as flotation chemicals, with Fenton process was investigated. Fenton process seems advantageous for this treatment, because of Fe(2+) content and low pH of AMD. First, optimum Fe(2+) condition under constant H(2)O(2) was determined, and initial Fe(2+) content of AMD was found sufficient (120 mg/L for removal of chemical oxygen demand (COD) of 6125 mg/L). In the second step, without any additional Fe(2+), optimum H(2)O(2) dosage was determined as 40 mg/L. Fe(2+)/H(2)O(2) molar ratio of 1.8 was enough to achieve the best treatment performance. In all trials, initial pH of AMD was 4.8 and pH adjustment was not performed. Utilization of existing pH and Fe(2+), low H(2)O(2) requirements, and up to 98% treatment performances in COD, turbidity, color, Cu(2+), Zn(2+) made the proposed treatment system promising. Since the reaction occurs stepwise, a two-step kinetic model was applied and calculated theoretical maximum removal rate was consistent to experimental one, which validates the applied model. For the optimum molar ratio (1.8), 140 mL/L sludge of high density (1.094 g/mL), high settling velocity (0.16 cm/s) with low specific resistance (3.15 x 10(8)m/kg) was obtained. High reaction rates and easily dewaterable sludge characteristics also made the proposed method advantageous.
研究了采用芬顿法处理含有重金属、酸性矿山废水(AMD)以及浮选化学品的铜矿废水的可行性。由于AMD中的Fe(2+)含量和低pH值,芬顿法似乎有利于这种处理。首先,在H(2)O(2)恒定的条件下确定了最佳Fe(2+)条件,发现AMD的初始Fe(2+)含量足够(去除6125mg/L的化学需氧量(COD)时为120mg/L)。第二步,在不添加任何额外Fe(2+)的情况下,确定最佳H(2)O(2)用量为40mg/L。Fe(2+)/H(2)O(2)摩尔比为1.8足以实现最佳处理性能。在所有试验中,AMD的初始pH值为4.8,未进行pH调节。利用现有的pH值和Fe(2+)、低H(2)O(2)需求量以及高达98%的COD、浊度、颜色、Cu(2+)、Zn(2+)处理性能,使得所提出的处理系统很有前景。由于反应是分步进行的,应用了两步动力学模型,计算得到的理论最大去除率与实验结果一致,这验证了所应用的模型。对于最佳摩尔比(1.8),获得了高密度(1.094g/mL)、高沉降速度(0.16cm/s)和低比阻(3.15×10(8)m/kg)的140mL/L污泥。高反应速率和易于脱水的污泥特性也使得所提出的方法具有优势。
