allowable pulsatory torque

简明释义

许用脉动扭矩

英英释义

例句

1.The engineers calculated the allowable pulsatory torque 允许的脉动扭矩 for the new engine design to ensure optimal performance.

工程师们计算了新发动机设计的允许的脉动扭矩以确保最佳性能。

2.The manufacturer provided specifications for the allowable pulsatory torque 允许的脉动扭矩 to ensure safety standards were met.

制造商提供了允许的脉动扭矩的规格，以确保满足安全标准。

3.In the testing phase, we monitored the allowable pulsatory torque 允许的脉动扭矩 to prevent any mechanical failures.

在测试阶段，我们监测了允许的脉动扭矩以防止任何机械故障。

4.Adjusting the settings helped us stay within the allowable pulsatory torque 允许的脉动扭矩 limits during operation.

调整设置帮助我们在操作期间保持在允许的脉动扭矩限制之内。

5.Understanding the allowable pulsatory torque 允许的脉动扭矩 is crucial for the longevity of rotating machinery.

理解允许的脉动扭矩对旋转机械的寿命至关重要。

作文

In the realm of mechanical engineering, understanding the concept of allowable pulsatory torque is crucial for the design and analysis of various systems. This term refers to the maximum torque that can be applied to a rotating component without causing damage or failure due to oscillations or fluctuations in the torque levels. The significance of allowable pulsatory torque lies in its ability to ensure the reliability and longevity of machinery, particularly in applications where dynamic loads are prevalent.When engineers design a system, they must consider the forces and torques that will act upon it during operation. Pulsatory torque is often encountered in systems such as engines, turbines, and electric motors, where the rotational speed and load can vary significantly. If the applied torque exceeds the allowable pulsatory torque, it may lead to material fatigue, excessive wear, or even catastrophic failure of the components involved.To effectively manage allowable pulsatory torque, engineers utilize various methods of analysis and testing. Finite element analysis (FEA) is a common technique used to simulate the effects of pulsatory torque on materials and structures. By modeling the behavior of components under different loading conditions, engineers can identify potential weaknesses and optimize designs accordingly. Additionally, testing prototypes under controlled conditions allows for the empirical determination of allowable pulsatory torque values, ensuring that safety margins are maintained during actual operation.The implications of exceeding the allowable pulsatory torque are not limited to mechanical failure alone. In many industries, such as aerospace and automotive, the consequences of a failure can extend to safety risks for personnel and significant financial losses. Therefore, adhering to the defined limits of allowable pulsatory torque is essential not only for the integrity of the machinery but also for the safety of individuals who operate or work near these systems.Moreover, the concept of allowable pulsatory torque is not static; it can change based on several factors, including material properties, environmental conditions, and the specific application. For instance, the allowable limits may differ between a high-performance racing engine and a standard consumer vehicle due to the varying demands placed on each system. Engineers must remain vigilant and continuously update their understanding of allowable pulsatory torque as new materials and technologies emerge.In conclusion, the term allowable pulsatory torque plays a vital role in the field of mechanical engineering. It encompasses the maximum permissible torque fluctuations that a system can endure without compromising its functionality or safety. By thoroughly analyzing and understanding this concept, engineers can design more robust and reliable machinery, ultimately leading to enhanced performance and reduced risk of failure. As technology advances, the importance of accurately determining and adhering to allowable pulsatory torque will only become more pronounced, underscoring the need for ongoing research and development in this area.

在机械工程领域，理解允许脉动扭矩的概念对各种系统的设计和分析至关重要。这个术语指的是可以施加于旋转部件的最大扭矩，而不会因扭矩水平的振荡或波动而导致损坏或故障。允许脉动扭矩的重要性在于它能够确保机械的可靠性和长寿命，特别是在动态负载普遍存在的应用中。当工程师设计系统时，他们必须考虑在操作过程中将施加于其上的力和扭矩。脉动扭矩通常出现在发动机、涡轮机和电动机等系统中，这些系统的转速和负载可能会显著变化。如果施加的扭矩超过了允许脉动扭矩，可能会导致材料疲劳、过度磨损，甚至部件的灾难性故障。为了有效管理允许脉动扭矩，工程师采用各种分析和测试方法。有限元分析（FEA）是一种常用的技术，用于模拟脉动扭矩对材料和结构的影响。通过在不同加载条件下对组件行为进行建模，工程师可以识别潜在的弱点并相应地优化设计。此外，在受控条件下对原型进行测试，可以经验性地确定允许脉动扭矩值，确保在实际操作期间保持安全裕度。超出允许脉动扭矩的影响不仅限于机械故障。在航空航天和汽车等许多行业中，故障的后果可能扩展到对人员的安全风险和重大的经济损失。因此，遵循定义的允许脉动扭矩限制对于机械的完整性以及操作或在这些系统附近工作的个人的安全至关重要。此外，允许脉动扭矩的概念并不是静态的；它可能会根据多个因素而变化，包括材料特性、环境条件和特定应用。例如，由于每个系统所承受的不同要求，高性能赛车发动机和标准消费者车辆之间的允许极限可能会有所不同。工程师必须保持警惕，并随着新材料和技术的出现不断更新对允许脉动扭矩的理解。总之，术语允许脉动扭矩在机械工程领域发挥着至关重要的作用。它涵盖了系统可以承受的最大允许扭矩波动，而不会影响其功能或安全性。通过彻底分析和理解这一概念，工程师可以设计出更坚固、更可靠的机械，从而最终提高性能并减少故障风险。随着技术的发展，准确确定和遵循允许脉动扭矩的重要性只会变得更加明显，突显出在这一领域持续研究和开发的必要性。