high energy gas fracturing

简明释义

高能气伐压裂;

英英释义

例句

1.The environmental impact of high energy gas fracturing is a topic of ongoing debate among scientists.

关于高能气体压裂的环境影响是科学家们持续争论的话题。

2.The oil company decided to use high energy gas fracturing to enhance the extraction of natural gas from deep shale formations.

该石油公司决定使用高能气体压裂来增强从深层页岩中提取天然气的效率。

3.The research team studied the effects of high energy gas fracturing on reservoir pressure and recovery rates.

研究小组研究了高能气体压裂对储层压力和采收率的影响。

4.By implementing high energy gas fracturing, we were able to significantly increase the flow rate of oil in the wells.

通过实施高能气体压裂，我们能够显著提高井中的石油流量。

5.Using high energy gas fracturing can lead to more efficient resource extraction compared to traditional methods.

与传统方法相比，使用高能气体压裂可以更有效地提取资源。

作文

In recent years, the energy sector has witnessed significant advancements in extraction technologies, particularly in the field of natural gas. One such innovative method is high energy gas fracturing, which has revolutionized the way we access and produce natural gas from deep underground reservoirs. This technique involves injecting high-pressure gas into rock formations to create fractures, allowing gas to flow more freely to the surface. The efficiency and effectiveness of high energy gas fracturing have made it a preferred choice for many energy companies seeking to maximize their output while minimizing environmental impact.The process of high energy gas fracturing begins with the identification of suitable geological formations that contain natural gas. Engineers and geologists work together to analyze data and determine the best locations for drilling. Once a site is selected, a well is drilled deep into the earth, reaching the gas-bearing rock layers. After the well is prepared, the fracturing process can begin.During high energy gas fracturing, a mixture of gas, water, and additives is injected into the well at extremely high pressures. This injection creates fractures in the surrounding rock, which increases the permeability of the formation. By enhancing the flow pathways for the gas, this method allows for a more efficient extraction process. One of the key advantages of using gas instead of traditional water-based fracturing fluids is that it reduces the risk of contamination to groundwater sources and minimizes the volume of wastewater generated during the process.Moreover, high energy gas fracturing has been found to be particularly effective in shale formations, where traditional drilling methods may not yield sufficient gas production. Shale gas has become an essential component of the global energy supply, and the ability to extract it efficiently is crucial for meeting the increasing energy demands of the world.Despite its numerous benefits, high energy gas fracturing is not without its controversies. Environmental concerns have been raised regarding the potential for induced seismicity, or small earthquakes, as a result of the fracturing process. Additionally, there are worries about the long-term impacts on local ecosystems and water resources. As a response to these concerns, many companies are investing in research and development to improve the safety and sustainability of high energy gas fracturing techniques.In conclusion, high energy gas fracturing represents a significant advancement in the field of natural gas extraction. By utilizing high-pressure gas to fracture rock formations, this method enhances the efficiency of gas production while aiming to reduce environmental risks. As the world continues to seek cleaner and more sustainable energy sources, the role of high energy gas fracturing will likely become even more prominent in the energy landscape. Balancing the benefits of increased gas production with the need for environmental protection will be crucial as we navigate the future of energy extraction.

近年来，能源行业在提取技术方面经历了重大进展，尤其是在天然气领域。其中一种创新方法是高能气体压裂，它彻底改变了我们从地下深处油气藏中获取和生产天然气的方式。这项技术涉及将高压气体注入岩层中以产生裂缝，从而使气体能够更自由地流向地表。高能气体压裂的效率和有效性使其成为许多能源公司在最大化产量同时最小化环境影响时的首选。高能气体压裂的过程始于识别适合的地质构造，这些构造中含有天然气。工程师和地质学家共同合作，分析数据并确定钻探的最佳位置。一旦选择了地点，就会在地下深处钻出一口井，达到含气岩层。在井准备好后，压裂过程就可以开始了。在高能气体压裂过程中，将气体、水和添加剂的混合物以极高的压力注入井中。这种注入在周围的岩石中创造出裂缝，从而增加了构造的渗透性。通过增强气体的流动通道，这种方法允许更高效的提取过程。使用气体而不是传统的水基压裂液的一个关键优势是，它减少了对地下水源污染的风险，并最小化了在此过程中产生的废水量。此外，高能气体压裂在页岩构造中被发现特别有效，而传统的钻探方法可能无法产生足够的气体产量。页岩气已成为全球能源供应的重要组成部分，高效提取它的能力对于满足世界日益增长的能源需求至关重要。尽管有许多好处，高能气体压裂也并非没有争议。人们对压裂过程可能导致诱发地震（即小型地震）的潜在环境问题表示担忧。此外，人们还担心对当地生态系统和水资源的长期影响。作为对此类担忧的回应，许多公司正在投资研究和开发，以提高高能气体压裂技术的安全性和可持续性。总之，高能气体压裂代表了天然气提取领域的一项重大进展。通过利用高压气体来压裂岩层，这种方法提高了气体生产的效率，同时旨在减少环境风险。随着世界继续寻求更清洁和可持续的能源来源，高能气体压裂在能源格局中的作用可能会变得更加突出。在我们导航未来的能源提取时，平衡气体生产的好处与环境保护的需求将至关重要。