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浅论铝盐的水解和吸附电中和过程中被凝聚物浓度的影响
引用本文:王晓昌. 浅论铝盐的水解和吸附电中和过程中被凝聚物浓度的影响[J]. 环境化学, 1996, 15(6): 530-535
作者姓名:王晓昌
作者单位:西安建筑科技大学!西安710055
摘    要:通过对凝聚机理和铝盐在水中水解过程的分析,提出了铝盐水解物吸附起胶本电和中和数学模式,论述了被凝聚物浓度对铝盐水解过程的影响,在实际的凝集过程中,铝盐的水解和向胶体表面的吸附是同时进行的,部分铝盐在完成水解之前就以中间产物的形态吸附于胶体表面,胶体溶液的浓度愈高,这种倾向就愈强,由于较低水解度的物种具有较高的单位电位浓度,它们能显示较强的电中和能力,因此,随着胶体溶液浓度增高,达到最佳凝聚ζ电位所

关 键 词:铝盐 水解 吸附电中和 ζ电位 凝聚物浓度

CHARACTERISTICS OF ALUMINUM COAGULATION: THE INFLUENCE OF SUSPENSION CONCENTRATION ON HYDROLYSIS REACTION AND ADSORPTION-CHARGE NEUTRALIZATION
Wang Xiaochang. CHARACTERISTICS OF ALUMINUM COAGULATION: THE INFLUENCE OF SUSPENSION CONCENTRATION ON HYDROLYSIS REACTION AND ADSORPTION-CHARGE NEUTRALIZATION[J]. Environmental Chemistry, 1996, 15(6): 530-535
Authors:Wang Xiaochang
Abstract:In this paper,the author has proposed a mathematical model to describe the process of adsorption and charge neutralization by hydrolyzed aluminum species on the basis of coagulation mechanism. The influence of suspension concentration on aluminum hydrolysis was discussed. As an aluminum salt is dosed to a suspension,the adsorption of aluminum species on the surface of the suspended particles may compete with aluminum hydrolysis arid some of the less hydrolyzed species may have already been adsorbed before the completion of hydrolysis reaction. Such a tendency may become stronger when the suspension concentration is higher.Because the less hydrolyzed aluminum species have higher specific positive charge,they are more effective in neutralizing the negative charge of the suspended particles. Therefore, as the suspension concentration becomes higher,the specific aluminum dosage required for neutralizing the particles to an optimum zeta potential for coagulation is decreased substantially. This gives a reasonable explanation of the non-stoichiometric relation between aluminum dosage and suspension concentration.
Keywords:aluminum hydrolysis  adsorption-charge neutralization  zeta potential.  
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