thrust-eccentric effect

简明释义

推力偏心效应

英英释义

例句

1.Understanding the thrust-eccentric effect is crucial for improving the design of jet engines.

理解推力偏心效应对于改善喷气发动机设计至关重要。

2.The researchers observed that the thrust-eccentric effect caused unexpected vibrations in the structure.

研究人员观察到，推力偏心效应导致结构出现意外振动。

3.In aerospace engineering, the thrust-eccentric effect can lead to increased wear on components.

在航空航天工程中，推力偏心效应可能导致组件的磨损加剧。

4.To mitigate the thrust-eccentric effect, engineers designed a new mounting system.

为了减轻推力偏心效应，工程师设计了一种新的安装系统。

5.The engineer calculated the impact of the thrust-eccentric effect on the stability of the rocket during launch.

工程师计算了在发射过程中，推力偏心效应对火箭稳定性的影响。

作文

In the field of engineering, particularly in the design and analysis of rotating machinery, understanding various phenomena is crucial for ensuring optimal performance and safety. One such phenomenon is the thrust-eccentric effect (推力偏心效应), which can significantly impact the behavior of mechanical systems. This effect arises when there is an imbalance in the thrust generated by rotating components, leading to uneven forces acting on the system. As a result, this can cause vibrations, misalignment, and ultimately, premature failure of machinery. The thrust-eccentric effect (推力偏心效应) is often observed in applications like turbines, engines, and pumps where rotating elements are subject to significant forces. When these components rotate, they generate thrust that ideally should be evenly distributed. However, if the thrust is not perfectly aligned with the center of rotation, it creates a situation where the forces are eccentric, meaning they do not act through the center of mass. This misalignment can lead to a variety of issues, including excessive wear on bearings, increased energy consumption, and even catastrophic failures in extreme cases.One of the primary causes of the thrust-eccentric effect (推力偏心效应) is manufacturing tolerances. Even minor deviations from the ideal geometry of components can lead to significant thrust imbalances. For example, if a shaft is slightly bent or if the rotor is not perfectly balanced, the thrust produced during operation will not be centered. Engineers must take these factors into account during the design process to minimize the potential for eccentric thrust.To mitigate the thrust-eccentric effect (推力偏心效应), designers often employ several strategies. One common approach is to use counterweights or balancing techniques to ensure that the rotating components maintain a uniform distribution of mass. Additionally, advanced materials and manufacturing techniques can improve the precision of components, reducing the likelihood of thrust imbalances. Regular maintenance and monitoring of machinery can also help detect any signs of the thrust-eccentric effect (推力偏心效应) early, allowing for timely interventions before serious damage occurs.Moreover, understanding the thrust-eccentric effect (推力偏心效应) is vital for predictive maintenance practices. By analyzing vibration patterns and thrust measurements, engineers can identify abnormalities that indicate the presence of eccentric thrust. This data-driven approach allows for proactive measures, enhancing the reliability and lifespan of machinery.In conclusion, the thrust-eccentric effect (推力偏心效应) is a critical concept in mechanical engineering that highlights the importance of precise design and manufacturing. By recognizing and addressing this phenomenon, engineers can improve the performance, efficiency, and safety of rotating machinery. As technology advances, the tools available for analyzing and mitigating the thrust-eccentric effect (推力偏心效应) continue to evolve, paving the way for more robust and reliable engineering solutions.

在工程领域，特别是在旋转机械的设计和分析中，理解各种现象对于确保最佳性能和安全至关重要。其中一个现象是推力偏心效应（thrust-eccentric effect），它会显著影响机械系统的行为。该效应出现在旋转部件产生的推力不平衡时，导致作用于系统的不均匀力。因此，这可能导致振动、失调，最终导致机械的提前故障。推力偏心效应（thrust-eccentric effect）通常出现在涡轮机、发动机和泵等应用中，其中旋转元件承受着显著的力。当这些部件旋转时，它们产生的推力理想情况下应该是均匀分布的。然而，如果推力没有完美地与旋转中心对齐，就会造成一个情况，即作用力是偏心的，意味着它们并不通过质心。这种失调可能导致多种问题，包括轴承过度磨损、能耗增加，甚至在极端情况下发生灾难性故障。推力偏心效应（thrust-eccentric effect）的主要原因之一是制造公差。即使是微小的几何偏差也可能导致显著的推力不平衡。例如，如果轴稍微弯曲或转子没有完美平衡，则在操作过程中产生的推力将不会集中。工程师必须在设计过程中考虑这些因素，以尽量减少偏心推力的潜在可能性。为了减轻推力偏心效应（thrust-eccentric effect），设计师通常采用几种策略。一种常见的方法是使用配重或平衡技术，以确保旋转部件保持均匀的质量分布。此外，先进的材料和制造技术可以提高部件的精度，从而减少推力不平衡的可能性。定期维护和监测机械设备也可以帮助及早发现任何推力偏心效应（thrust-eccentric effect）的迹象，从而在严重损坏发生之前进行及时干预。此外，理解推力偏心效应（thrust-eccentric effect）对于预测性维护实践至关重要。通过分析振动模式和推力测量，工程师可以识别异常现象，表明存在偏心推力。这种数据驱动的方法允许采取主动措施，提高机械的可靠性和使用寿命。总之，推力偏心效应（thrust-eccentric effect）是机械工程中的一个关键概念，强调了精确设计和制造的重要性。通过认识和解决这一现象，工程师可以改善旋转机械的性能、效率和安全性。随着技术的进步，分析和减轻推力偏心效应（thrust-eccentric effect）的工具不断发展，为更强大和可靠的工程解决方案铺平了道路。