bottomhole flowing pressure

简明释义

1. 井底流动压力; 2. 井底流压;

英英释义

例句

1.The engineer calculated the bottomhole flowing pressure to optimize the production rate.

工程师计算了底 hole 流动压力以优化生产率。

2.Monitoring the bottomhole flowing pressure is crucial for assessing reservoir performance.

监测底 hole 流动压力对于评估油藏性能至关重要。

3.During the test, the bottomhole flowing pressure was recorded every hour.

在测试期间，底 hole 流动压力每小时记录一次。

4.The team used a simulator to predict the bottomhole flowing pressure under different conditions.

团队使用模拟器预测不同条件下的底 hole 流动压力。

5.An increase in bottomhole flowing pressure can indicate a potential blockage in the well.

增加的底 hole 流动压力可能表明井中存在潜在堵塞。

作文

In the field of petroleum engineering, understanding various pressure measurements is crucial for optimizing oil and gas production. One such important term is bottomhole flowing pressure, which refers to the pressure at the bottom of a well when the fluid is flowing. This measurement is essential for engineers to determine the performance of the reservoir and the efficiency of the production system. The bottomhole flowing pressure plays a significant role in reservoir management, as it helps in assessing the driving forces behind fluid movement within the reservoir. By analyzing this pressure, engineers can make informed decisions about enhancing production techniques and implementing secondary recovery methods.The bottomhole flowing pressure is influenced by various factors, including the fluid properties, wellbore conditions, and reservoir characteristics. For instance, the viscosity of the oil or gas being extracted can significantly affect the pressure readings. Higher viscosity fluids tend to create more resistance to flow, leading to increased bottomhole flowing pressure. Conversely, lighter fluids may exhibit lower pressure levels. Understanding these dynamics allows engineers to adjust their extraction strategies accordingly.Moreover, measuring the bottomhole flowing pressure is vital during well testing. It provides insights into the reservoir’s behavior and helps in identifying potential issues such as formation damage or gas breakthrough. Engineers can use this data to optimize well completion designs and improve overall recovery rates. For example, if the bottomhole flowing pressure is found to be consistently high, it may indicate that the well is underperforming due to blockages or other complications. Addressing these issues promptly can lead to enhanced production outcomes.In addition to its role in production optimization, the bottomhole flowing pressure is also essential for safety considerations. Monitoring this pressure helps prevent blowouts and other hazardous situations that may arise from sudden changes in pressure conditions. By maintaining a close watch on the bottomhole flowing pressure, operators can ensure that the well remains stable and that any fluctuations are addressed before they escalate into serious problems.Furthermore, advancements in technology have improved our ability to measure and analyze bottomhole flowing pressure. With the advent of digital sensors and real-time monitoring systems, engineers can now obtain accurate pressure readings instantaneously. This technological progress not only enhances our understanding of reservoir behavior but also facilitates quicker decision-making processes. As a result, companies can respond more effectively to changing conditions and maintain optimal production levels.In conclusion, the term bottomhole flowing pressure encapsulates a critical aspect of petroleum engineering that directly impacts oil and gas production. Its significance lies in its ability to inform engineers about reservoir performance, guide extraction strategies, and ensure operational safety. As technology continues to advance, our capacity to measure and interpret bottomhole flowing pressure will only improve, leading to more efficient and sustainable practices in the energy sector. Understanding this concept is not merely an academic exercise; it is fundamental to the success and safety of modern petroleum operations.

在石油工程领域，理解各种压力测量对于优化石油和天然气生产至关重要。其中一个重要术语是底孔流动压力，它指的是当流体流动时井底的压力。这个测量对工程师来说是评估储层性能和生产系统效率的关键。底孔流动压力在储层管理中发挥着重要作用，因为它有助于评估储层内流体运动背后的驱动力。通过分析这种压力，工程师可以就增强生产技术和实施二次采收方法做出明智的决策。底孔流动压力受多种因素的影响，包括流体特性、井筒条件和储层特征。例如，被提取的油或气的粘度会显著影响压力读数。粘度较高的流体往往会产生更多的流动阻力，从而导致底孔流动压力增加。相反，较轻的流体可能表现出较低的压力水平。理解这些动态使工程师能够相应地调整其提取策略。此外，测量底孔流动压力在井测试期间至关重要。它提供了关于储层行为的见解，并有助于识别潜在问题，例如地层损害或气体突破。工程师可以利用这些数据来优化井完井设计并提高总体采收率。例如，如果发现底孔流动压力持续偏高，这可能表明由于堵塞或其他并发症，井的表现不佳。及时解决这些问题可以带来更好的生产结果。除了在生产优化中的作用外，底孔流动压力对于安全考虑也至关重要。监测该压力有助于防止喷井和其他可能因压力条件突然变化而引发的危险情况。通过密切关注底孔流动压力，操作人员可以确保井的稳定，并在波动升级为严重问题之前解决任何波动。此外，技术的进步改善了我们测量和分析底孔流动压力的能力。随着数字传感器和实时监测系统的出现，工程师现在可以即时获得准确的压力读数。这一技术进步不仅增强了我们对储层行为的理解，还促进了更快的决策过程。因此，公司可以更有效地响应变化的条件，并保持最佳的生产水平。总之，底孔流动压力这一术语概括了石油工程的一个关键方面，直接影响着石油和天然气生产。它的重要性在于能够告知工程师储层性能、指导提取策略并确保操作安全。随着技术的不断进步，我们测量和解释底孔流动压力的能力将进一步提高，从而推动能源行业更加高效和可持续的实践。理解这一概念不仅仅是学术练习；它是现代石油作业成功与安全的基础。