artificial permeability

简明释义

1. 人工渗透率; 2. 人工渗透性;

英英释义

例句

1.In geotechnical engineering, understanding artificial permeability is crucial for groundwater management.

在岩土工程中，理解人工渗透性对地下水管理至关重要。

2.The artificial permeability of the soil was increased by adding polymer additives.

通过添加聚合物添加剂，土壤的人工渗透性得到了提高。

3.The study focused on the effects of temperature on artificial permeability in porous media.

该研究集中于温度对多孔介质中人工渗透性的影响。

4.The researchers conducted experiments to measure the artificial permeability of the new composite material.

研究人员进行了实验，以测量新复合材料的人工渗透性。

5.Engineers designed a system to enhance the artificial permeability of the barrier layer.

工程师设计了一个系统，以增强屏障层的人工渗透性。

作文

In the field of geology and engineering, the concept of artificial permeability plays a crucial role in understanding fluid movement through various materials. Artificial permeability refers to the ability of a material to allow fluids to pass through it, which has been enhanced through human intervention or technological processes. This concept is particularly significant in areas such as petroleum extraction, groundwater management, and environmental remediation. By artificially increasing the permeability of certain materials, engineers and scientists can optimize fluid flow and improve the efficiency of various operations.One of the primary applications of artificial permeability is in the oil and gas industry. In many cases, natural reservoirs may have low permeability, making it difficult for oil or gas to flow freely. To tackle this issue, techniques such as hydraulic fracturing are employed, which involve injecting high-pressure fluids into the rock formations. This process creates fractures within the rock, thereby increasing its artificial permeability and allowing hydrocarbons to flow more easily to the production wells. The success of hydraulic fracturing has revolutionized the energy sector, leading to increased production rates and reduced reliance on imported fuels.Another important application of artificial permeability is in the realm of groundwater management. In urban areas, the natural permeability of soil can be significantly altered due to construction and other human activities. This alteration can lead to issues such as flooding and waterlogging. To mitigate these problems, engineers often implement drainage systems or permeable pavements that enhance the artificial permeability of the ground. By allowing rainwater to infiltrate the soil more effectively, these systems help recharge groundwater supplies and reduce surface runoff, ultimately contributing to sustainable water management practices.Environmental remediation is yet another area where artificial permeability proves beneficial. Contaminated sites often require the removal of pollutants from the soil and groundwater. One effective method is to enhance the permeability of the contaminated medium, allowing for better access of remediation agents, such as chemicals or microorganisms, to the pollutants. Techniques like soil washing or bioremediation can be more effective when artificial permeability is introduced, as they facilitate the movement of these agents throughout the contaminated area, leading to faster and more efficient clean-up processes.However, while the benefits of artificial permeability are numerous, there are also challenges and potential drawbacks associated with its implementation. For instance, increasing permeability can sometimes lead to unintended consequences, such as the migration of contaminants to previously unaffected areas. Therefore, careful planning and monitoring are required to ensure that the enhancement of permeability does not compromise environmental integrity or public health.In conclusion, artificial permeability is a vital concept that underscores the intersection of natural processes and human innovation. Its applications in oil and gas extraction, groundwater management, and environmental remediation highlight its importance in addressing some of the most pressing challenges faced by modern society. As technology continues to evolve, the methods for enhancing artificial permeability will likely become more sophisticated, paving the way for more efficient and sustainable resource management in the future.

在地质和工程领域，人工渗透性的概念在理解流体通过各种材料的运动中起着至关重要的作用。人工渗透性是指材料允许流体通过的能力，这种能力通过人为干预或技术过程得到了增强。这个概念在石油开采、地下水管理和环境修复等领域尤为重要。通过人工提高某些材料的渗透性，工程师和科学家可以优化流体流动，提高各种操作的效率。人工渗透性的主要应用之一是在石油和天然气行业。在许多情况下，自然储层可能具有低渗透性，使得石油或天然气难以自由流动。为了解决这个问题，采用了水力压裂等技术，该技术涉及将高压流体注入岩石形成。这一过程在岩石内产生裂缝，从而提高其人工渗透性，使碳氢化合物更容易流向生产井。水力压裂的成功彻底改变了能源行业，导致生产率提高，并减少对进口燃料的依赖。人工渗透性的另一个重要应用是在地下水管理领域。在城市地区，由于建设和其他人类活动，土壤的自然渗透性可能会显著改变。这种变化可能导致洪水和积水等问题。为了减轻这些问题，工程师通常实施排水系统或透水铺装，增强地面的人工渗透性。通过更有效地让雨水渗入土壤，这些系统有助于补充地下水资源，减少地表径流，最终促进可持续水管理实践。环境修复是另一个人工渗透性证明有益的领域。受污染的场所通常需要从土壤和地下水中去除污染物。一种有效的方法是提高受污染介质的渗透性，从而改善修复剂（如化学品或微生物）对污染物的接触。土壤洗涤或生物修复等技术在引入人工渗透性时可以更有效，因为它们促进了这些剂在受污染区域的运动，从而加快和更高效的清理过程。然而，虽然人工渗透性的好处众多，但其实施也面临挑战和潜在缺点。例如，提高渗透性有时可能导致意想不到的后果，如污染物迁移到之前未受影响的区域。因此，需要仔细的规划和监测，以确保渗透性的增强不会危害环境完整性或公共健康。总之，人工渗透性是一个重要的概念，强调了自然过程与人类创新的交汇点。它在石油和天然气提取、地下水管理和环境修复中的应用突显了其在解决现代社会面临的一些最紧迫挑战中的重要性。随着技术的不断发展，增强人工渗透性的方法可能变得更加复杂，为未来更高效和可持续的资源管理铺平道路。