缓释过程中水中镁离子的去除效率

Yaroslav Radovenchyk, Kateryna Hordiienko, T. Krysenko, V. Radovenchyk
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Its use in the processes of removing calcium ions allows to ensure the residual hardness of water at the level of 0.1 - 0.2 mg-eq/dm3 in a wide range of temperatures and hydrogen index. Detailed studies of the use of sodium phosphate in the processes of removing magnesium ions showed its insufficient efficiency. \nThe effectiveness of soda-sodium softening allows to ensure at pH 11.0 - 11.5 the residual hardness of water at the level of 0.4 - 0.6 mg-eq/dm3. But the need to adjust the hydrogen index and the high consumption of reagents make this technology unsuitable for widespread use. The determining factor in water softening processes using phosphate ions is the ratio between the concentrations of phosphate ions and magnesium ions K = [PO43-, mg-eq] / [Mg2+, mg-eq]. Taking into account the strict requirements of current regulatory documents for the content of phosphates in treated waters, it is desirable to carry out the treatment with stoichiometric ratios of reagents for a more complete reaction between the components. The advantage of sodium phosphate as a reagent for removing magnesium ions can be considered the fact that in the pH range of 3.16 - 10.07 at K = 1, the residual hardness ranges from 1.8 to 3.4 mg-eq/dm3. At the same time, the minimum value of the residual stiffness was recorded at the level of 0.75 mg-eq/dm3 at pH 10.07 and K = 2. As the pH decreases, a stable decrease in efficiency is observed, although it is not very significant. Thus, during the transition from an alkaline to an acidic medium, the residual concentration of magnesium ions increases by a factor of 2, regardless of the value of the coefficient K. Similar trends persist in the case of a change in the initial hardness of water. The biggest difference is observed at values ​​of K ≤ 1, which is explained by the deficiency of phosphate anions and the impossibility of forming a solid phase of stoichiometric composition. However, even with a stoichiometric ratio of reactants (K = 1), the residual hardness of treated water is quite significant and ranges from 2.5 to 3 mg-eq/dm3. A further increase in the dose of sodium phosphate allows to slightly reduce the residual hardness of the treated water. Thus, the minimum residual hardness of treated water at K = 2.0 is fixed at the level of 0.7 mg-eq/dm3 with an initial hardness of 22.9 mg-eq/dm3. An increase in the residual hardness of the treated water with a decrease in its initial hardness was also noted. 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引用次数: 0

摘要

天然水中钙和镁离子的显著浓度迫使大多数家庭饮用水和能源水经过初步软化。因此,缓解技术在今天变得特别紧迫,这一领域的研究每年都在增加。由于水的硬度是由钙和镁离子的总含量决定的,所以这些元素是这类研究的重点。传统上,人们认为钙离子首先被去除,而镁离子不太可能形成固相。然而,软化技术的有效性同样取决于这两种阳离子。因此,对镁离子也应给予足够的重视。磷酸钠被认为是一种很有前途的试剂。它用于去除钙离子的过程中,可以确保在广泛的温度和氢指数范围内,水的剩余硬度在0.1 - 0.2 mg-eq/dm3的水平。对磷酸钠在脱除镁离子过程中的应用进行了详细的研究,表明其效率不足。钠-钠软化的有效性可以确保在pH 11.0 - 11.5时,水的剩余硬度在0.4 - 0.6 mg-eq/dm3的水平。但由于需要调整氢指数和试剂的高消耗,使得该技术不适合广泛应用。磷酸盐离子软化水过程的决定因素是磷酸盐离子与镁离子浓度之比K = [PO43-, mg-eq] / [Mg2+, mg-eq]。考虑到当前法规文件对处理水中磷酸盐含量的严格要求,为了使各组分之间的反应更完全,需要使用试剂的化学计量比进行处理。磷酸钠作为脱除镁离子试剂的优势在于,在pH为3.16 ~ 10.07,K = 1时,残余硬度为1.8 ~ 3.4 mg-eq/dm3。同时,在pH 10.07、K = 2条件下,在0.75 mg-eq/dm3水平下,记录了残余刚度的最小值。随着pH值的降低,可以观察到效率的稳定下降,尽管不是很显著。因此,在从碱性介质到酸性介质的转变过程中,镁离子的残留浓度增加了2倍,而与系数k的值无关。在水的初始硬度发生变化的情况下,也存在类似的趋势。K≤1时差异最大,这是由于磷酸盐阴离子缺乏,不可能形成化学计量组成的固相。然而,即使在反应物的化学计量比(K = 1)下,处理后的水的剩余硬度也相当显著,范围在2.5至3 mg-eq/dm3之间。进一步增加磷酸钠的剂量可以稍微降低处理过的水的残余硬度。因此,当K = 2.0时,处理水的最小剩余硬度固定在0.7 mg-eq/dm3,初始硬度为22.9 mg-eq/dm3。还注意到处理过的水的残余硬度增加而其初始硬度降低。在我们看来,这种情况是由于固相质量的显著增加和pH值随着磷酸钠剂量的增加而增加造成的。磷酸钠作为钙离子沉淀剂的一个显著优点是,在很宽的温度范围内,水的温度实际上不影响工艺的效率。这种趋势也是镁离子的特征。在5 ~ 70℃的温度范围内,软化效率保持稳定。此外,固相在排干溶液后立即形成。如果我们考虑到磷酸盐去除钙离子的高效率,那么一般来说,只要形成的固相与水完全分离,就可以允许使用磷酸盐软化水。通过沉淀或过滤分离磷酸镁颗粒的效率的详细研究与固相形成过程同样重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Efficiency of magnesium ions removal from water in processes of its mitigation
Significant concentrations of calcium and magnesium ions in natural waters force the majority of domestic drinking and energy waters to undergo preliminary softening. Therefore, mitigation technologies are becoming particularly acute today, and research in this field is increasing every year. Since water hardness is determined by the total content of calcium and magnesium ions, these elements are the focus of such research. Traditionally, it is believed that calcium ions are the first to be removed, and magnesium ions are less likely to form a solid phase. However, the effectiveness of softening technology depends equally on both cations. Therefore, sufficient attention should also be paid to magnesium ions. Sodium phosphate is considered a promising reagent in this direction. Its use in the processes of removing calcium ions allows to ensure the residual hardness of water at the level of 0.1 - 0.2 mg-eq/dm3 in a wide range of temperatures and hydrogen index. Detailed studies of the use of sodium phosphate in the processes of removing magnesium ions showed its insufficient efficiency. The effectiveness of soda-sodium softening allows to ensure at pH 11.0 - 11.5 the residual hardness of water at the level of 0.4 - 0.6 mg-eq/dm3. But the need to adjust the hydrogen index and the high consumption of reagents make this technology unsuitable for widespread use. The determining factor in water softening processes using phosphate ions is the ratio between the concentrations of phosphate ions and magnesium ions K = [PO43-, mg-eq] / [Mg2+, mg-eq]. Taking into account the strict requirements of current regulatory documents for the content of phosphates in treated waters, it is desirable to carry out the treatment with stoichiometric ratios of reagents for a more complete reaction between the components. The advantage of sodium phosphate as a reagent for removing magnesium ions can be considered the fact that in the pH range of 3.16 - 10.07 at K = 1, the residual hardness ranges from 1.8 to 3.4 mg-eq/dm3. At the same time, the minimum value of the residual stiffness was recorded at the level of 0.75 mg-eq/dm3 at pH 10.07 and K = 2. As the pH decreases, a stable decrease in efficiency is observed, although it is not very significant. Thus, during the transition from an alkaline to an acidic medium, the residual concentration of magnesium ions increases by a factor of 2, regardless of the value of the coefficient K. Similar trends persist in the case of a change in the initial hardness of water. The biggest difference is observed at values ​​of K ≤ 1, which is explained by the deficiency of phosphate anions and the impossibility of forming a solid phase of stoichiometric composition. However, even with a stoichiometric ratio of reactants (K = 1), the residual hardness of treated water is quite significant and ranges from 2.5 to 3 mg-eq/dm3. A further increase in the dose of sodium phosphate allows to slightly reduce the residual hardness of the treated water. Thus, the minimum residual hardness of treated water at K = 2.0 is fixed at the level of 0.7 mg-eq/dm3 with an initial hardness of 22.9 mg-eq/dm3. An increase in the residual hardness of the treated water with a decrease in its initial hardness was also noted. This situation is caused, in our opinion, by a significant increase in the mass of the solid phase and an increase in pH with an increase in the dose of sodium phosphate. A significant advantage of sodium phosphate as a precipitator of calcium ions is the fact that the temperature of the water practically does not affect the efficiency of the process in a wide range of temperatures. This trend is also characteristic of magnesium ions. In the temperature range of 5 - 70 °C, the softening efficiency remains stable. Moreover, the solid phase is formed immediately after draining the solutions. If we take into account the high efficiency of phosphates in removing calcium ions, then in general, the use of phosphates for softening water can be permissible, provided that the formed solid phase is completely separated from the water. Detailed studies of the efficiency of separation of magnesium phosphate particles by settling or filtering are as important as the processes of solid phase formation.
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