液体在低温下的蒸发

Yaroslav Radovenchyk, T. Krysenko, M. Poberezhnyi
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引用次数: 0

摘要

乌克兰企业每年产生数百万立方米的矿化水,这些水被排放到地面水库,以及数百万立方米的高浓度溶液和悬浮液,这些溶液和悬浮液被积累并储存在特殊的污泥储存库中。这种废水对环境造成了无法弥补的破坏。不久前,人们提出了一种利用具有毛细特性的纤维材料蒸发工业浓缩物的新方法。使用这些材料,可以创建一个有效、自主、廉价和极其简单的系统,用于各种液体和浓缩物的蒸发。研究方法如下:在我们的研究中使用了两个相同直径的刻度圆柱体。一个圆柱体中装满了一定程度的液相,用来控制水介质表面的蒸发。在另一个实验圆柱体中,另外放置了一条垂直的棉条(从1层到21层织物)。条的宽度为5厘米。条带长度为50 cm。棉花密度为100 g/m2。研究方法是确定沿织物条的液相毛细管上升高度,并评估在设定温度下两个圆柱体中蒸发的液体体积的减少。结果表明,在无风条件下,垂直放置条带之间7 ~ 15mm的距离足以保证最大蒸发强度。我们在自然条件下的长期实验证实了所提出方法的高效率。在日平均气温为2.3℃的情况下,白天织物表面有明显的蒸发现象。在这种情况下,没有观察到水面的蒸发。应当注意的是,自然条件下的蒸发强度取决于相当多的因素(温度、风速、光度、湿度等),因此很难检测到其中一些因素之间的直接关系。随着液相温度的升高,蒸发效率降低。在温度为20℃时,实验室安装(15层棉条)使蒸发强度增加了2倍以上,在46℃时增加了5倍以上,在57℃时增加了近3倍,但在75℃时仅增加了约67%。很明显,仅液相加热对织物条表面蒸发过程的影响较小,织物条在较低温度的大气中迅速冷却。因此,为了提高蒸发强度,必须提高液-织物系统各组分的温度。一种性能合适的织物,在两个金属架之间拉伸,下端浸入液相中,就可以用作简单的蒸发器。我们的研究表明,在处理液体溶液时使用具有毛细管特性的材料,可以创造出简单、廉价和高效的设备,用于蒸发水并将液体废物转化为固体相。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evaporation of liquids at low temperatures
Ukrainian enterprises annually generate millions cubic meters of mineralized water, which is discharged into surface reservoirs, and millions cubic meters of highly concentrated solutions and suspensions, which are accumulated and stored in special sludge storages. This waste water causes irreparable damage to the environment. A new method for the evaporation of industrial concentrates by fibrous materials with capillary properties was proposed not so long ago. The use of such materials allows an effective, autonomous, cheap, and extremely simple system to be created for the evaporation for various liquids and concentrates. The research methodology was as follows. Two graduated cylinders of the same diameter were used in our research. One cylinder was filled with the liquid phase to a certain level and used to control evaporation from the surface of the aqueous medium. In the other, experimental cylinder, a vertical cotton strip was additionally placed (from 1 to 21 layers of fabric). The width of the strip was 5 cm. The length of the strip was 50 cm. The density of cotton was 100 g/m2. The research method was to determine the height of liquid phase capillary rise along the strip of fabric and to evaluate reduction in the volume of liquid that evaporates in both cylinders at set temperatures. It was found that in the absence of wind and the distance between the vertically placed strips of 7–15 mm were sufficient to ensure the maximum evaporation intensity. Our long-term experiments in natural conditions confirmed the high efficiency of the proposed method. At an average daily air temperature of 2.3 °C, there was a significant evaporation from the surface of the fabric during the day. In this case, evaporation from the water surface was not observed. It should be noted that the intensity of evaporation under natural conditions depends on a significant number of factors (temperature, wind speed, luminosity, humidity, etc.), so it is difficult to detect a direct relationship between some of them. With increase only in the liquid phase temperature, the evaporation efficiency decreased. At a temperature of 20 °C, the laboratory installation (15 layers of cotton strip) increased the evaporation intensity by more than 2 times, at 46 °C by more than 5 times, at 57 °C by almost 3 times, but at 75 °C only by about 67 %. It is obvious that heating of the liquid phase alone less influences the evaporation process from the surface of the fabric strip, which was cooled rapidly in the atmosphere at a much lower temperature. Therefore, to increase the evaporation intensity, it is necessary to increase temperature for all components of the liquid–fabric system. A fabric with suitable properties, stretched between two metal racks and immersed into the liquid phase with the lower end, can be used as a simple evaporator. Our research has shown that the use of materials with capillary properties in the treatment of liquid solutions allows simple, cheap, and efficient devices to be created for evaporating water and converting liquid waste into a solid phase.
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