flow permeability

简明释义

透水性

英英释义

例句

1.The flow permeability of concrete can affect the durability of structures exposed to moisture.

混凝土的流动渗透性会影响暴露在潮湿环境中的结构的耐久性。

2.High flow permeability in gravel allows for rapid water movement, making it ideal for drainage systems.

砾石的流动渗透性高，允许水快速移动，因此非常适合排水系统。

3.A material with low flow permeability can prevent unwanted water infiltration into buildings.

具有低流动渗透性的材料可以防止水分不必要地渗入建筑物。

4.In hydrogeology, understanding flow permeability is crucial for groundwater modeling.

在水文地质学中，理解流动渗透性对地下水建模至关重要。

5.The engineer measured the flow permeability of the soil to determine its ability to drain water effectively.

工程师测量了土壤的流动渗透性以确定其有效排水能力。

作文

Understanding the concept of flow permeability is essential in various fields, including geology, engineering, and environmental science. Flow permeability refers to the ability of a material to allow fluids to pass through it. This property is particularly important when analyzing soil and rock formations, as it affects water movement, contaminant transport, and overall ecosystem health.In geology, flow permeability plays a crucial role in groundwater studies. High flow permeability in soil or rock means that water can easily flow through these materials, which can lead to the replenishment of aquifers. Conversely, low flow permeability indicates that water moves slowly, which may result in waterlogging or reduced groundwater recharge. Understanding these dynamics helps geologists predict how water will behave in different environments, aiding in resource management and conservation efforts.Moreover, in civil engineering, flow permeability is a key factor when designing foundations and drainage systems. Engineers must consider the flow permeability of the ground when constructing buildings, roads, and other infrastructures. If the ground has high flow permeability, engineers might need to implement additional drainage solutions to prevent flooding or erosion. On the other hand, if the ground has low flow permeability, it may be necessary to design systems that can efficiently manage runoff and prevent water accumulation.Environmental scientists also rely on the concept of flow permeability when assessing the impact of pollutants in soil and water systems. When contaminants are introduced into an environment, their movement is heavily influenced by the flow permeability of the surrounding materials. High flow permeability can facilitate the rapid spread of pollutants, making it more challenging to contain and remediate contaminated sites. Therefore, understanding the flow permeability of different materials can help in developing effective strategies for pollution management and environmental protection.In agriculture, flow permeability affects irrigation practices and soil health. Farmers need to understand the flow permeability of their soil to optimize water usage and ensure crops receive adequate moisture. Soils with high flow permeability may require more frequent watering, while those with low flow permeability could retain moisture for longer periods. This knowledge allows farmers to make informed decisions about irrigation scheduling and soil amendments, ultimately leading to better crop yields and sustainable farming practices.In conclusion, the concept of flow permeability is vital across multiple disciplines. Its implications reach far beyond simple fluid movement; it influences groundwater management, civil engineering projects, environmental health, and agricultural practices. By gaining a deeper understanding of flow permeability, professionals in these fields can make informed decisions that enhance sustainability and resource management. As we continue to face challenges related to water scarcity and environmental degradation, the importance of flow permeability will only grow, highlighting the need for ongoing research and education in this critical area.

理解流动渗透性的概念对于地质学、工程学和环境科学等多个领域至关重要。流动渗透性是指材料允许流体通过的能力。这一特性在分析土壤和岩石层时尤其重要，因为它影响水的运动、污染物的传播以及整体生态系统的健康。在地质学中，流动渗透性在地下水研究中发挥着关键作用。土壤或岩石中的高流动渗透性意味着水可以轻易通过这些材料流动，这可能导致含水层的补给。相反，低流动渗透性表示水的移动缓慢，这可能导致水涝或地下水补给减少。理解这些动态有助于地质学家预测水在不同环境中的行为，从而帮助资源管理和保护工作。此外，在土木工程中，流动渗透性是设计基础和排水系统时的一个关键因素。工程师在建造建筑物、道路和其他基础设施时必须考虑地面的流动渗透性。如果地面具有高流动渗透性，工程师可能需要实施额外的排水解决方案，以防止洪水或侵蚀。另一方面，如果地面具有低流动渗透性，则可能需要设计能够有效管理径流并防止水积聚的系统。环境科学家在评估土壤和水系统中污染物的影响时也依赖于流动渗透性的概念。当污染物被引入环境时，其运动受到周围材料的流动渗透性的严重影响。高流动渗透性可能促进污染物的快速传播，使得控制和修复受污染场所更加困难。因此，理解不同材料的流动渗透性可以帮助制定有效的污染管理和环境保护策略。在农业中，流动渗透性影响灌溉实践和土壤健康。农民需要了解其土壤的流动渗透性以优化水的使用，确保作物获得足够的水分。具有高流动渗透性的土壤可能需要更频繁的浇水，而具有低流动渗透性的土壤则可能长时间保持水分。这一知识使农民能够就灌溉调度和土壤改良做出明智的决策，最终提高作物产量和可持续农业实践。总之，流动渗透性的概念在多个学科中至关重要。它的影响远不止于简单的流体运动；它影响地下水管理、土木工程项目、环境健康和农业实践。通过深入理解流动渗透性，这些领域的专业人士可以做出明智的决策，增强可持续性和资源管理。随着我们继续面临与水资源短缺和环境退化相关的挑战，流动渗透性的重要性只会增加，这突显了在这一关键领域进行持续研究和教育的必要性。