filtrability

简明释义

英[fɪltrəˈbɪləti]美[fɪltrəˈbɪləti]

n. 过滤性（等于 filterability）

英英释义

单词用法

同义词

反义词

例句

1.Hydraulic fluid power. Fluids. Measurement of filtrability of HFC and HFD class fire resistant fluids.

液压流体动力。流体。HFC和HF d类防火流体的可过滤性测量。

2.Hydraulic fluid power. Fluids. Measurement of filtrability of HFC and HFD class fire resistant fluids.

液压流体动力。流体。HFC和HF d类防火流体的可过滤性测量。

3.The filtrability of the water sample was tested to ensure it met safety standards.

水样的过滤性被测试以确保符合安全标准。

4.In this experiment, we measured the filtrability of different soils to determine their suitability for agriculture.

在这个实验中，我们测量了不同土壤的过滤性以确定它们的农业适宜性。

5.Improving the filtrability of the membrane can enhance the efficiency of the filtration process.

改善膜的过滤性可以提高过滤过程的效率。

6.The filtrability of the oil sample was crucial for its processing in the refinery.

油样的过滤性对于其在炼油厂的加工至关重要。

7.Researchers found that the filtrability of the liquid increased with temperature.

研究人员发现，液体的过滤性随着温度的升高而增加。

作文

In the world of science and engineering, the term filtrability refers to the ease with which a fluid can pass through a filter. This concept is particularly significant in various industries, including water treatment, pharmaceuticals, and food processing. Understanding filtrability is crucial for optimizing processes that require the separation of solids from liquids, ensuring that the final product meets quality standards and is safe for consumption. One of the primary factors affecting filtrability is the size and nature of the particles suspended in the fluid. For instance, in water treatment facilities, the presence of larger particles can significantly hinder the filtrability of water, necessitating pre-treatment steps to remove these contaminants. Techniques such as coagulation and sedimentation are often employed to enhance filtrability by aggregating smaller particles into larger ones that can be easily filtered out. Moreover, the type of filter used plays a critical role in determining filtrability. Filters come in various forms, including membrane filters, sand filters, and activated carbon filters, each designed for specific applications. The choice of filter material, pore size, and thickness can either facilitate or impede the filtrability of the fluid. For example, a filter with a very fine mesh might effectively remove small particles but could also lead to reduced flow rates, making it less efficient in certain scenarios. In addition to physical properties, the chemical composition of the fluid can also influence its filtrability. Fluids with high viscosity tend to have lower filtrability, as their thicker consistency makes it more difficult for them to flow through filters. Therefore, understanding the rheological properties of a fluid is essential for predicting its filtrability. In some cases, additives may be introduced to alter the viscosity of the fluid, thereby improving its filtrability. Furthermore, temperature can impact filtrability. Higher temperatures generally decrease the viscosity of liquids, allowing for easier flow through filters. This principle is often utilized in industrial processes where heating is applied to improve filtrability during filtration operations. However, it is important to consider that increased temperatures can also affect the integrity of certain filter materials, potentially leading to premature failure. The significance of filtrability extends beyond industrial applications; it is also vital in environmental contexts. For example, in natural water bodies, the filtrability of water affects the health of aquatic ecosystems. Poor filtrability can lead to the accumulation of pollutants, which can harm fish and other wildlife. Thus, monitoring and managing the filtrability of water sources is essential for maintaining ecological balance. In conclusion, filtrability is a multifaceted concept that plays a pivotal role in various fields. By understanding the factors that influence filtrability, professionals can design more efficient filtration systems, ensuring that fluids are processed effectively and safely. Whether in industrial settings or environmental conservation efforts, the principles of filtrability remain fundamental to achieving desired outcomes.

在科学和工程领域，术语filtrability指的是流体通过过滤器的难易程度。这个概念在水处理、制药和食品加工等多个行业中尤为重要。理解filtrability对优化需要固体与液体分离的过程至关重要，确保最终产品符合质量标准且安全可供消费。 影响filtrability的主要因素之一是悬浮在流体中的颗粒的大小和性质。例如，在水处理设施中，大颗粒的存在会显著阻碍水的filtrability，因此需要进行预处理步骤以去除这些污染物。通常采用絮凝和沉淀等技术来增强filtrability，通过将较小的颗粒聚集成较大的颗粒，从而可以轻松过滤掉。 此外，所使用的过滤器类型在决定filtrability方面也起着关键作用。过滤器有多种形式，包括膜过滤器、砂过滤器和活性炭过滤器，每种过滤器都设计用于特定的应用。过滤材料、孔径和厚度的选择可能会促进或阻碍流体的filtrability。例如，具有非常细网眼的过滤器可能有效去除小颗粒，但也可能导致流速降低，使其在某些情况下效率较低。 除了物理属性外，流体的化学成分也会影响其filtrability。高粘度的流体往往具有较低的filtrability，因为它们的粘稠性使得流体更难通过过滤器。因此，了解流体的流变特性对于预测其filtrability至关重要。在某些情况下，可能会引入添加剂来改变流体的粘度，从而改善其filtrability。 此外，温度也会影响filtrability。较高的温度通常会降低液体的粘度，使其更容易通过过滤器流动。这个原理常用于工业过程中，通过加热来改善过滤操作中的filtrability。然而，需要考虑的是，温度升高可能会影响某些过滤材料的完整性，可能导致过滤器过早失效。 filtrability的重要性不仅限于工业应用；在环境背景中也至关重要。例如，在自然水体中，水的filtrability影响着水生生态系统的健康。较差的filtrability可能导致污染物的积累，从而危害鱼类和其他野生动物。因此，监测和管理水源的filtrability对于维持生态平衡至关重要。 总之，filtrability是一个多方面的概念，在各个领域发挥着关键作用。通过理解影响filtrability的因素，专业人士可以设计出更高效的过滤系统，确保流体被有效且安全地处理。无论是在工业环境还是环境保护工作中，filtrability的原则始终是实现预期结果的基础。