{"title":"气-水平衡对碳酸盐沉淀影响的量化","authors":"Lilly Zacherl, Thomas Baumann","doi":"10.1186/s40517-023-00256-4","DOIUrl":null,"url":null,"abstract":"<div><p>The expanding geothermal energy sector still faces performance issues due to scalings in pipes and surface level installations, which require elevated operation pressure levels and costly maintenance. For facilities in the North Alpine Foreland Basin, the precipitation of <span>\\({\\hbox {CaCO}}_{3}\\)</span> is the main problem which is a consequence of the disruption of the lime-carbonic acid equilibrium during production. The formation of gas bubbles plays a key role in the scaling process. This work presents experiments in a bubble column to quantify the effects of gas stripping on carbonate precipitation and an extension of PhreeqC to include kinetic exchange between a gas phase and water for the simulation of the experimental results. With the same hybrid model not only precipitation of <span>\\({\\hbox {CaCO}}_{3}\\)</span> but also the dissolution of scalings by the injection of <span>\\({\\hbox {CO}}_{2}\\)</span> could be quantified. The bubble column was filled with tap water and brine. By varying the ionic strength of the solution, a wider range of geothermal waters was covered. Air and <span>\\({\\hbox {CO}}_{2}\\)</span> were introduced at the bottom. The precipitates built on the column wall were analyzed with Raman spectroscopy: injecting air into tap water at low ionic strength led to the formation of aragonite with 59.8% of the precipitates remaining at the column wall and the rest as particles in dispersion. At moderate ionic strength the dominant polymorph was calcite and 81.5% of the crystals were attached to the wall. At high ionic strength precipitation was inhibited. The presence of crystallization nuclei reduced the time for precipitation, but not the amount of scalings formed. Injecting <span>\\({\\hbox {CO}}_{2}\\)</span> into the solution completely removed the scalings from the column wall. The model and its experimental backup lay the foundation for a process-based prediction of the scales (not only) in geothermal systems.</p></div>","PeriodicalId":48643,"journal":{"name":"Geothermal Energy","volume":"11 1","pages":""},"PeriodicalIF":2.9000,"publicationDate":"2023-04-30","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://geothermal-energy-journal.springeropen.com/counter/pdf/10.1186/s40517-023-00256-4","citationCount":"0","resultStr":"{\"title\":\"Quantification of the effect of gas–water–equilibria on carbonate precipitation\",\"authors\":\"Lilly Zacherl, Thomas Baumann\",\"doi\":\"10.1186/s40517-023-00256-4\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>The expanding geothermal energy sector still faces performance issues due to scalings in pipes and surface level installations, which require elevated operation pressure levels and costly maintenance. For facilities in the North Alpine Foreland Basin, the precipitation of <span>\\\\({\\\\hbox {CaCO}}_{3}\\\\)</span> is the main problem which is a consequence of the disruption of the lime-carbonic acid equilibrium during production. The formation of gas bubbles plays a key role in the scaling process. This work presents experiments in a bubble column to quantify the effects of gas stripping on carbonate precipitation and an extension of PhreeqC to include kinetic exchange between a gas phase and water for the simulation of the experimental results. With the same hybrid model not only precipitation of <span>\\\\({\\\\hbox {CaCO}}_{3}\\\\)</span> but also the dissolution of scalings by the injection of <span>\\\\({\\\\hbox {CO}}_{2}\\\\)</span> could be quantified. The bubble column was filled with tap water and brine. By varying the ionic strength of the solution, a wider range of geothermal waters was covered. Air and <span>\\\\({\\\\hbox {CO}}_{2}\\\\)</span> were introduced at the bottom. The precipitates built on the column wall were analyzed with Raman spectroscopy: injecting air into tap water at low ionic strength led to the formation of aragonite with 59.8% of the precipitates remaining at the column wall and the rest as particles in dispersion. At moderate ionic strength the dominant polymorph was calcite and 81.5% of the crystals were attached to the wall. At high ionic strength precipitation was inhibited. The presence of crystallization nuclei reduced the time for precipitation, but not the amount of scalings formed. Injecting <span>\\\\({\\\\hbox {CO}}_{2}\\\\)</span> into the solution completely removed the scalings from the column wall. 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引用次数: 0
摘要
由于管道和地面设施的结垢,不断扩大的地热能源行业仍然面临性能问题,这些问题需要更高的运行压力水平和昂贵的维护费用。对于北阿尔卑斯前陆盆地的设施,\({\hbox {CaCO}}_{3}\)的降水是主要问题,这是生产过程中石灰-碳酸平衡被破坏的结果。气泡的形成在结垢过程中起着关键作用。这项工作提出了在气泡柱中进行的实验,以量化气提对碳酸盐沉淀的影响,并扩展了PhreeqC,以包括气相和水之间的动力学交换,以模拟实验结果。在相同的混合模型下,不仅可以量化\({\hbox {CaCO}}_{3}\)的沉淀,还可以量化\({\hbox {CO}}_{2}\)注入对结垢的溶解。气泡柱中装满了自来水和盐水。通过改变溶液的离子强度,可以覆盖更大范围的地热水。在底部引入空气和\({\hbox {CO}}_{2}\)。用拉曼光谱分析柱壁上的沉淀物:在低离子强度下向自来水中注入空气,形成59.8的文石% of the precipitates remaining at the column wall and the rest as particles in dispersion. At moderate ionic strength the dominant polymorph was calcite and 81.5% of the crystals were attached to the wall. At high ionic strength precipitation was inhibited. The presence of crystallization nuclei reduced the time for precipitation, but not the amount of scalings formed. Injecting \({\hbox {CO}}_{2}\) into the solution completely removed the scalings from the column wall. The model and its experimental backup lay the foundation for a process-based prediction of the scales (not only) in geothermal systems.
Quantification of the effect of gas–water–equilibria on carbonate precipitation
The expanding geothermal energy sector still faces performance issues due to scalings in pipes and surface level installations, which require elevated operation pressure levels and costly maintenance. For facilities in the North Alpine Foreland Basin, the precipitation of \({\hbox {CaCO}}_{3}\) is the main problem which is a consequence of the disruption of the lime-carbonic acid equilibrium during production. The formation of gas bubbles plays a key role in the scaling process. This work presents experiments in a bubble column to quantify the effects of gas stripping on carbonate precipitation and an extension of PhreeqC to include kinetic exchange between a gas phase and water for the simulation of the experimental results. With the same hybrid model not only precipitation of \({\hbox {CaCO}}_{3}\) but also the dissolution of scalings by the injection of \({\hbox {CO}}_{2}\) could be quantified. The bubble column was filled with tap water and brine. By varying the ionic strength of the solution, a wider range of geothermal waters was covered. Air and \({\hbox {CO}}_{2}\) were introduced at the bottom. The precipitates built on the column wall were analyzed with Raman spectroscopy: injecting air into tap water at low ionic strength led to the formation of aragonite with 59.8% of the precipitates remaining at the column wall and the rest as particles in dispersion. At moderate ionic strength the dominant polymorph was calcite and 81.5% of the crystals were attached to the wall. At high ionic strength precipitation was inhibited. The presence of crystallization nuclei reduced the time for precipitation, but not the amount of scalings formed. Injecting \({\hbox {CO}}_{2}\) into the solution completely removed the scalings from the column wall. The model and its experimental backup lay the foundation for a process-based prediction of the scales (not only) in geothermal systems.
Geothermal EnergyEarth and Planetary Sciences-Geotechnical Engineering and Engineering Geology
CiteScore
5.90
自引率
7.10%
发文量
25
审稿时长
8 weeks
期刊介绍:
Geothermal Energy is a peer-reviewed fully open access journal published under the SpringerOpen brand. It focuses on fundamental and applied research needed to deploy technologies for developing and integrating geothermal energy as one key element in the future energy portfolio. Contributions include geological, geophysical, and geochemical studies; exploration of geothermal fields; reservoir characterization and modeling; development of productivity-enhancing methods; and approaches to achieve robust and economic plant operation. Geothermal Energy serves to examine the interaction of individual system components while taking the whole process into account, from the development of the reservoir to the economic provision of geothermal energy.