Grinding mills are commonly used in mineral beneficiation to reduce particle size. The corrosion of metallic grinding media and mill liner is a very serious problem, particularly in acidic conditions as encountered in the Florida phosphate fertilizer industry. Cathodic protection using impressed current was investigated to reduce the wear rate during ball milling.; A statistical Box-Behnken Design (BBD) of experiments was performed to evaluate effects of individual variables and their interactions on wear rate of grinding ball mill. The optimum process parameters for minimum wear rate for 1018 carbon steel were solution pH at 7.4, rotation speed at 70 RPM, solid percentage at 76% by weight, and crop load at 72% by volume. For high chromium alloy, optimum parameters were solution pH at 8.7, rotation speed at 61 RPM, solid percentage at 65% by weight, and crop load at 58% by volume.; The effects of polarization potential and impressed current density on corrosion rate were studied using a specially designed ball mill whose electrochemical potential was controlled. The required polarization potential to effectively reduce the wear rate of 1018 carbon steel was -1.0 V in pH 3.1 solution, -0.9 V in pH 6.8 solution, and -0.85 V in pH 9.2 solution, while the required current density for 1018 carbon steel was 210 mA/m2 at pH 3.1, 180 mA/m2 at pH 6.8, and 160 mA/m2 at pH 9.2. Experimental results indicate that the total wear rate was reduced by 41% to 46% and corrosive wear rate was reduced by 83% to 85% for 1018 carbon steel when a potential of -1.0 V was applied at pH's of 3.1 to 9.2. Similar results were obtained with the high chromium alloy.; The cathodic protection mechanisms of grinding mill were investigated in extensive fundamental studies. SEM images suggested that pitting corrosion was the main corrosion type. The corrosion products were deduced from the element ratio on the coupon surface by EDS. XRD images showed that Fe 2O3 was the main corrosion product for 1018 carbon steel in pH 3.1 solution without cathodic protection, while Fe 2O3, Fe3O4 and Fe(OH)3 were the corrosion products in neutral and alkaline solutions. XRD images also indicated that the corrosion was significantly reduced since most of the corrosion products disappeared from the coupon surfaces when polarization potential was applied. These conclusions are consistent with those obtained from Eh-pH diagrams.
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机译:磨粉机通常用于矿物选矿以减小粒度。金属研磨介质和磨机衬板的腐蚀是一个非常严重的问题,尤其是在佛罗里达磷肥工业中遇到的酸性条件下。研究了使用外加电流进行阴极保护以减少球磨过程中的磨损率。进行了统计Box-Behnken设计(BBD)实验,以评估各个变量及其相互作用对磨球磨机磨损率的影响。对于1018碳钢而言,最小磨损率的最佳工艺参数是:溶液的pH值为7.4,转速为70 RPM,固体成分的含量为76%(重量),农作物的负载量为72%(体积)。对于高铬合金,最佳参数是溶液的pH值为8.7,转速为61 RPM,固体百分含量为65%(重量),农作物负荷为58%(体积)。使用专门设计的电化学势可控的球磨机研究了极化电势和外加电流密度对腐蚀速率的影响。有效降低1018碳钢磨损率所需的极化电位在pH 3.1溶液中为-1.0 V,在pH 6.8溶液中为-0.9 V,在pH 9.2溶液中为-0.85 V,而1018碳钢的所需电流密度为在pH 3.1时为210 mA / m2,在pH 6.8时为180 mA / m2,在pH 9.2时为160 mA / m2。实验结果表明,当在3.1至9.2的pH值下施加-1.0 V的电势时,1018碳钢的总磨损率降低41%至46%,腐蚀磨损率降低83%至85%。用高铬合金获得了相似的结果。在广泛的基础研究中研究了磨机的阴极保护机理。 SEM图像表明点蚀是主要的腐蚀类型。通过EDS从试样表面的元素比率推导腐蚀产物。 XRD图像表明,Fe 2O3是1018碳钢在pH 3.1溶液中没有阴极保护的主要腐蚀产物,而Fe 2O3,Fe3O4和Fe(OH)3是中性和碱性溶液中的腐蚀产物。 XRD图像还表明,由于施加了极化电势后,大多数腐蚀产物从试样表面消失,腐蚀显着降低。这些结论与从Eh-pH图获得的结论一致。
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