单乙二醇MEG系统的水垢管理综述

M. Seiersten, S. Kundu
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引用次数: 3

摘要

本文回顾了MEG用于水合物抑制时出现的操作问题,特别是当MEG再生和再循环时。热力学平衡软件可以在一定程度上评估结垢风险。利用像碳酸钙这样的成核和结垢物的生长数据可以提高预测的准确性。当MEG溶液在CaCO3中过饱和时,MEG的存在和MEG系统中遇到的条件有利于文石结晶。MEG延缓了这三种CaCO3多晶的生长速度,但文石的减少幅度小于方解石和水晶石。MEG也减缓了菱铁矿的生长速度。然而,MEG并没有抑制碳酸盐的成核和生长。当采出水中含有钙时,再生MEG中的碱度会增加MEG注入点下游的结垢风险。阻垢剂可以减轻结垢,但选择过程必须确保化学品在相关条件下进行测试;即,具有预期的MEG浓度、碱度和ph值。许多MEG回收装置都有一个预处理系统,用于控制碳酸盐和某种程度上的氢氧化物的去除。这减少了再生系统中可能形成的水垢。在预处理中,以氢氧化物和/或碳酸盐形式加入的碱度迫使钙、锶、铁碳酸盐和氢氧化镁析出。过饱和度通常很高,阻垢剂无法阻止固体的沉淀。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Scale Management in Monoethylene Glycol MEG Systems - A Review
The paper reviews operational issues that arise when MEG is used for hydrate inhibition, especially when it is regenerated and recirculated. Thermodynamic equilibrium software can assess the scaling risk to some extent. Utilisation of data on nucleation and growth of scale formers like calcium carbonate can enhance the accuracy of the predictions. The presence of MEG and the conditions encountered in MEG systems favour aragonite crystallisation when the MEG solutions become supersaturated in CaCO3. MEG retards the growth rate of all three CaCO3 polymorphs, but the reduction is smaller for aragonite than for calcite and vaterite. The growth rate of siderite is also slowed down by MEG. However, MEG does not inhibit the nucleation and growth of carbonates. Alkalinity in recycled MEG will enhance the scaling risk downstream of the MEG injection point when there is calcium in the produced water. Scale can be mitigated by scale inhibitors, but the selection process must ensure that the chemicals are tested at relevant conditions; i.e. with the expected MEG concentration, alkalinity and pH. Many MEG recovery units have a pre-treatment system for controlled removal of carbonates and to some extent hydroxides. This reduces the amount of scale that may form in the regeneration system. In the pre-treatment, alkalinity dosed as hydroxide and/or carbonate forces precipitation of calcium, strontium and iron carbonates and magnesium hydroxide. The supersaturation is generally so high that scale inhibitors are not able to prevent precipitation of the solids.
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