应用超细气泡通过氮气净化方案对采掘水和自来水进行脱氧处理

IF 0.4 Q4 ENVIRONMENTAL SCIENCES

Asian Journal of Water, Environment and Pollution Pub Date : 2023-11-27 DOI:10.3233/ajw230077

W. S. Abdul-Majeed, S. Al-Dawery, Saada Al Shukaili, Chandramouli Thotireddy, Ibrahim Al Amri

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引用次数: 0

摘要

在本研究中，我们介绍了在超微细气泡（平均尺寸为 18 μm）规模的氮气吹扫下，对用于产水和自来水除氧的气提塔进行检查的结果。实验针对的是聚丙烯酰胺浓度为 300 ppm、体积粘度为 5 mPa.s 的采出水样品。在进行一系列实验后，根据塔内水位的不同，在不同的时间限制内，所有检查过的操作方案（半批次和一次通过）都能达到 0 ppm DO。将零溶解氧水平作为目标函数，结果表明，与普通气泡尺寸（毫米级）相比，在不同方案中采用超细气泡净化实验后，达到 0 ppm 溶解氧的效果提高了 5.7-14 倍。结果表明，氮气流量为 3 升/分钟时，溶解氧在 23 分钟内达到小于 10 ppb；氮气流量为 5 升/分钟时，溶解氧在 28 分钟内达到小于 10 ppb。此外，采用超细气泡氮气吹扫后，除氧塔成功地以平衡的进水/出水流速完全连续运行。这是在脱氧塔运行达到稳定状态后实现的（对于 422 升经过检验的水样，运行时间约为 1 小时）。色谱柱中稳定的细小气泡云在处理进水流时非常有效，在相同的出水流量下，进水流的溶解氧直接达到 0 ppm。随着柱中水位的增加，细气泡层/云的密度增加，处理效率也随之提高。这一结果为完全去除生产水中的溶解氧提供了一种独特的方法/解决方案，可在工业上有效采用。

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Application of Ultra Fine Bubbles for Deoxygenation of Produced Water and Tap Water via Nitrogen Purging Scheme

In this study, we present our findings from examining a gas lift tower for produced and tap water de-oxygenation, applying the nitrogen purging at an ultra-fine bubble scale (18 μm average size). The experiments were conducted for produced water samples grafted with polyacrylamide concentration 300 ppm with a measured bulk viscosity of 5 mPa.s. Upon applying a series of experimental sets, 0 ppm DO was attained in all examined operational schemes (semi batch and once through) within various time limits, depending on the water level in the column. Considering the zero DO level as an objective function, the results showed an improvement of 5.7–14 folds in reaching the 0 ppm DO upon experimenting with the ultra-fine bubble purging in different schemes, compared with of the results obtained from the ordinary bubble size (mm scale). The results show that DO reached < 10 ppb within 23 minutes with nitrogen flowrate 3 L/min while DO reaching < 10 ppb within 28 minutes with nitrogen flowrate 5 L/min. Furthermore, implementing the ultra-fine bubble nitrogen purging was successful in running the de-oxygenation tower in a full continuous mode at a balanced inlet/outlet water flow rate. This has been done after reaching stability in the column operation (lasting around 1 hour for 422 L of examined water sample). The stable fine bubbles cloud in the column was quite efficient in treating water influent stream to be exited directly at 0 ppm DO within the same effluent flow rate. The treatment efficiency has shown an increase with increasing water level in the column, resulting in a denser layer/cloud of fine bubbles. This result suggests a unique approach/solution for the complete removal of DO from produced water, which is accounted effective to be adopted industrially

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来源期刊

Asian Journal of Water, Environment and Pollution ENVIRONMENTAL SCIENCES-

CiteScore

1.00

自引率

20.00%

发文量

期刊介绍： Asia, as a whole region, faces severe stress on water availability, primarily due to high population density. Many regions of the continent face severe problems of water pollution on local as well as regional scale and these have to be tackled with a pan-Asian approach. However, the available literature on the subject is generally based on research done in Europe and North America. Therefore, there is an urgent and strong need for an Asian journal with its focus on the region and wherein the region specific problems are addressed in an intelligent manner. In Asia, besides water, there are several other issues related to environment, such as; global warming and its impact; intense land/use and shifting pattern of agriculture; issues related to fertilizer applications and pesticide residues in soil and water; and solid and liquid waste management particularly in industrial and urban areas. Asia is also a region with intense mining activities whereby serious environmental problems related to land/use, loss of top soil, water pollution and acid mine drainage are faced by various communities. Essentially, Asians are confronted with environmental problems on many fronts. Many pressing issues in the region interlink various aspects of environmental problems faced by population in this densely habited region in the world. Pollution is one such serious issue for many countries since there are many transnational water bodies that spread the pollutants across the entire region. Water, environment and pollution together constitute a three axial problem that all concerned people in the region would like to focus on.