Freeze concentration (FC) was investigated focusing in terms of assessment towards benefiting industrial wastewater treatment. A new more productive crystalliser was aimed to be designed as the main component in a progressive freeze concentration (PFC) process, a more economical version of FC which forms ice crystals as a layer or a block on cooled surface. Subsequent analysis on its performance, a process optimisation and heat transfer study were intended following completion of design. As a result, a helical structured copper crystalliser was successfully developed and fabricated named coil crystalliser, designed in such a way to provide high surface area per coolant volume, easy scale up and practical. In the subsequent performance analysis carried out using glucose solution as simulated industrial wastewater treatment, it was found that the effective partition constant (K) was satisfactorily low at high circulation flowrates, low initial concentration and intermediate coolant temperature. Low coolant temperature of -10 °C was observed to cause high ice front growth rate which subsequently promote high solute entrapment in the ice layer formed, affecting its purity. High circulation flowrates of 1000 ml/min on the other hand resulted in low solute inclusion in solid phase thus giving out high ice purity. In terms of volume reduction, the highest achieved was 76.65 % and coolant temperature seems to influence the most where low temperatures resulted in high solution volume reduction as a consequence of high ice growth rate. A process optimisation employing Response Surface Methodology (RSM) in Statistica software to yield the optimum conditions to produce the best K, ice purity (IP) and solution volume reduction (�V) generated three regression models, which have been proven adequate by good R-squared, residual and Analysis of Variance (ANOVA) analysis. Interactions between process variables according to the model agree well with the fundamental theory of FC and finally optimum conditions for each response have been identified. The best K predicted was 0.17, 78.5 % for �V and 0.05 mg/ml for IP. In the subsequent heat transfer study standard lines for overall heat transfer coefficient (Uo) were plotted. The Uo lines then facilitate in generating a model to predict ice crystal mass produced, originated from a heat balance analysis. Error analyses have proven the model’s reliability with Rsquared of 0.997 and Absolute Average Relative Deviation (AARD) of 10.6% between experimental and model data, with the highest predicted mass of 973.2g
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机译:对冷冻浓度(FC)进行了评估,重点是评估以利于工业废水处理。旨在将新型高产结晶器设计为渐进冷冻浓缩(PFC)过程的主要成分,该过程是一种更经济的FC版本,可在冷却表面上形成一层或一块冰晶。设计完成后,将对其性能进行后续分析,优化工艺并进行传热研究。结果,成功开发并制造了一种螺旋结构的铜结晶器,称为线圈结晶器,其设计方式是使每冷却液体积的表面积大,易于放大且实用。在随后的使用葡萄糖溶液作为模拟工业废水处理的性能分析中,发现在高循环流量,低初始浓度和中间冷却液温度下,有效分配常数(K)令人满意地低。观察到-10°C的低冷却液温度会导致高的冰前沿生长速率,这随后会促使溶质截留在形成的冰层中,从而影响其纯度。另一方面,1000 ml / min的高循环流量导致固相中溶质的含量降低,从而获得高冰纯度。就体积减少而言,最高的结果是76.65%,而冷却剂温度似乎对影响最大的是低温,这是由于高冰的生长速度导致溶液体积大量减少的结果。使用Statistica软件中的响应表面方法(RSM)进行过程优化以产生最佳条件以产生最佳K,冰纯度(IP)和溶液体积减少量(?V)产生了三个回归模型,这些模型已被良好的R证明是足够的平方,残差和方差分析(ANOVA)分析。根据该模型,过程变量之间的相互作用与FC的基本理论非常吻合,最终确定了每种响应的最佳条件。预测的最佳K值为0.17,?V为78.5%,IP为0.05 mg / ml。在随后的传热研究中,绘制了总传热系数(Uo)的标准线。然后,Uo线有助于生成模型来预测源自热平衡分析的冰晶质量。误差分析证明了该模型的可靠性,Rsquared为0.997,实验数据与模型数据之间的绝对平均相对偏差(AARD)为10.6%,最高预测质量为973.2g
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