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本文评述了水分子的基本特性和参数、水的微观“结构”、离子水合作用及氢键的特性。通过水分子及其邻近介质Zeeman电子-质子多重谱线中的禁止三重-单一跃迁,概略地描述了较弱磁场影响水分子之间氢键统计平均数的可能机理的模型。分析了磁场对多水环境的离子胶体子系统的作用效应。表明这种磁铁矿类型的胶体粒子的磁偶极相互作用能是以使其在磁场高梯度区絮凝和富集,也足以使其絮凝物稳定防止遭到流体动力破坏,这些絮凝物是CaCO3的结晶可能核心。根据所提出的计算结果并在别的作者,尤其是前苏联作者所提交的数据的基础上,本文评述了水防垢磁化处理的条件和方法。
This article reviews the basic properties and parameters of water molecules, the microscopic “structure” of water, ionic hydration and hydrogen bonding properties. By triplicate - single transition in the Zeeman electron - proton multiplet of water molecules and their neighboring media, a model of the possible mechanism of the weak magnetic field affecting the statistical average number of hydrogen bonds between water molecules is briefly described. The effect of magnetic field on ion colloid subsystem in a multi-water environment is analyzed. It is shown that the magnetopolar interaction energy of colloidal particles of this magnetite type is such that they can be flocculated and enriched in a high gradient region of the magnetic field and also sufficient for the stability of their flocs against fluid dynamic destruction. These flocs are CaCO3 Crystallization may be the core. Based on the calculated results and the data submitted by other authors, especially the authors of the former Soviet Union, the paper reviews the conditions and methods of water and soil scaling magnetization.