artificial fractured well

简明释义

1. 人工裂缝井; 2. 人工压裂井;

英英释义

例句

1.Using an artificial fractured well allows for better fluid flow and improved extraction methods.

使用人工裂缝井可以实现更好的流体流动和改进的提取方法。

2.By implementing an artificial fractured well, we can significantly increase the production rate.

通过实施一个人工裂缝井，我们可以显著提高生产率。

3.The engineers designed an artificial fractured well to enhance oil recovery in the region.

工程师们设计了一个人工裂缝井以增强该地区的石油开采。

4.The artificial fractured well was strategically placed to maximize resource recovery.

该人工裂缝井被战略性地放置，以最大化资源回收。

5.The team conducted a study on the efficiency of artificial fractured wells in geothermal energy extraction.

团队对人工裂缝井在地热能提取中的效率进行了研究。

作文

In the realm of petroleum engineering, the term artificial fractured well refers to a type of well that has been intentionally created or modified to enhance its production capabilities. This process typically involves the injection of fluids into the rock formation surrounding the well, which creates fractures in the rock. These fractures allow oil or gas to flow more freely to the wellbore, thereby increasing the overall yield from the well. The concept of artificial fractured well is crucial for maximizing the extraction of hydrocarbons from reservoirs that would otherwise be too difficult or inefficient to exploit.The creation of an artificial fractured well is a complex process that requires careful planning and execution. Engineers must analyze the geological characteristics of the reservoir to determine the best approach for fracturing. This analysis includes studying the rock's permeability, porosity, and stress conditions. Once the appropriate strategy is established, a mixture of water, sand, and various chemicals is injected at high pressure into the well. This process is known as hydraulic fracturing or 'fracking.'One of the primary benefits of utilizing artificial fractured wells is the significant increase in production rates. Traditional wells may only extract a fraction of the available resources due to natural barriers within the rock formation. By creating artificial fractures, engineers can bypass these barriers and access previously unreachable reserves. This not only improves the economic viability of oil and gas projects but also contributes to energy security by increasing domestic production.However, the use of artificial fractured wells is not without its challenges and controversies. Environmental concerns have been raised regarding the potential for groundwater contamination and seismic activity associated with hydraulic fracturing. Critics argue that the chemicals used in the fracking fluid can seep into aquifers, posing risks to drinking water sources. Additionally, the injection of high-pressure fluids can induce small earthquakes in certain areas.To mitigate these risks, regulatory frameworks have been developed in many regions to ensure that artificial fractured wells are operated safely and responsibly. These regulations often require extensive environmental assessments before drilling begins and mandate monitoring during and after the fracturing process. Many companies are also investing in research to develop greener fracking technologies that minimize environmental impacts.In conclusion, artificial fractured wells play a vital role in modern oil and gas extraction, allowing for greater efficiency and productivity. While they present certain environmental challenges, ongoing advancements in technology and regulatory oversight aim to address these issues. As the world continues to seek sustainable energy solutions, the development and management of artificial fractured wells will remain a critical area of focus for the energy industry. Understanding this concept is essential for anyone involved in petroleum engineering or related fields, as it represents a significant advancement in our ability to harness natural resources effectively.

在石油工程领域，术语人工裂缝井指的是一种经过故意创建或修改以增强其生产能力的井。这一过程通常涉及将流体注入井周围的岩石层，从而在岩石中产生裂缝。这些裂缝使得石油或天然气能够更自由地流向井筒，从而增加井的整体产量。人工裂缝井的概念对于最大化从储层中提取碳氢化合物至关重要，这些储层在没有这种技术的情况下可能过于困难或低效。创建人工裂缝井是一个复杂的过程，需要仔细的规划和执行。工程师必须分析储层的地质特征，以确定最合适的裂缝方法。这种分析包括研究岩石的渗透性、孔隙率和应力条件。一旦确定了适当的策略，就会将水、沙子和各种化学物质的混合物以高压注入井中。这个过程被称为水力压裂或“压裂”。利用人工裂缝井的主要好处之一是生产率显著提高。传统的井可能只提取出可用资源的一小部分，因为岩石层内存在自然障碍。通过创建人工裂缝，工程师可以绕过这些障碍，访问以前无法到达的储备。这不仅提高了石油和天然气项目的经济可行性，还通过增加国内生产来促进能源安全。然而，使用人工裂缝井并非没有挑战和争议。关于水力压裂可能导致地下水污染和引发地震的环境问题引发了人们的担忧。批评者认为，压裂液中使用的化学物质可能渗入含水层，危及饮用水源。此外，高压流体的注入可能在某些地区引发小规模地震。为了减少这些风险，许多地区制定了监管框架，以确保人工裂缝井的安全和负责任运营。这些法规通常要求在钻探开始之前进行广泛的环境评估，并在压裂过程中和之后进行监测。许多公司也在投资研发更环保的压裂技术，以减少环境影响。总之，人工裂缝井在现代石油和天然气开采中扮演着至关重要的角色，能够实现更高的效率和生产力。虽然它们带来了某些环境挑战，但技术的不断进步和监管监督旨在解决这些问题。随着世界继续寻求可持续的能源解决方案，人工裂缝井的开发和管理将仍然是能源行业关注的关键领域。理解这一概念对于任何参与石油工程或相关领域的人来说都是至关重要的，因为它代表了我们有效利用自然资源的重大进步。