circumferential force

简明释义

切向力

英英释义

例句

1.The design of the wheel must account for the circumferential force 周向力 generated during motion.

轮子的设计必须考虑到运动过程中产生的周向力 circumferential force。

2.During the test, the team measured the circumferential force 周向力 on the rotating shaft.

在测试过程中，团队测量了旋转轴上的周向力 circumferential force。

3.Understanding the circumferential force 周向力 helps in predicting the failure points of cylindrical structures.

理解周向力 circumferential force 有助于预测圆柱形结构的失效点。

4.In a rotating system, the circumferential force 周向力 is crucial for maintaining stability.

在旋转系统中，周向力 circumferential force 对于维持稳定性至关重要。

5.The engineer calculated the circumferential force 周向力 acting on the pipe to ensure it could withstand the pressure.

工程师计算了作用在管道上的周向力 circumferential force，以确保它能够承受压力。

作文

In the field of physics and engineering, understanding the various forces that act on objects is crucial for designing structures and systems that can withstand different conditions. One such important concept is the circumferential force, which refers to the force exerted along the circumference of a circular object. This type of force is particularly significant in applications involving rotating machinery, cylindrical structures, and even in the design of vehicles. The circumferential force plays a vital role in ensuring stability and integrity during operation.To illustrate the significance of circumferential force, consider a simple example of a rotating wheel. As the wheel spins, the forces acting on it are not only vertical but also horizontal. The circumferential force is responsible for maintaining the wheel's rotation and ensuring that it does not collapse under its own weight or external loads. If the circumferential force is insufficient, the wheel may experience deformation or failure, leading to potential accidents.Moreover, in engineering design, understanding how to calculate and apply circumferential force is crucial for the safety and functionality of various structures. For instance, when designing a pipeline that carries fluids under pressure, engineers must consider the circumferential force that acts on the walls of the pipe. If the force exceeds the material's strength, it can lead to ruptures or leaks, posing environmental hazards and financial losses.The concept of circumferential force extends beyond mechanical applications; it is also relevant in civil engineering. When constructing bridges, for example, engineers must account for the circumferential force that occurs due to the weight of the bridge itself as well as the loads it will carry. Proper calculations ensure that the materials used can withstand these forces, thereby preventing structural failures.In addition to its practical applications, the study of circumferential force also provides insights into fundamental physics principles. It relates to concepts such as tension, compression, and shear forces. Understanding how these forces interact within a system helps scientists and engineers develop better models for predicting behavior under various conditions.Furthermore, advancements in technology have allowed for more precise measurements and simulations of circumferential force. With the use of computer-aided design (CAD) software and finite element analysis (FEA), engineers can visualize how forces distribute throughout a structure, enabling them to make informed decisions during the design process.In conclusion, the circumferential force is a fundamental concept in physics and engineering that has far-reaching implications in various fields. From ensuring the safety of rotating machinery to optimizing the design of infrastructure, understanding this force is essential for creating reliable and efficient systems. As technology continues to evolve, the methods for analyzing and applying circumferential force will undoubtedly advance, leading to even greater innovations in engineering and design.

在物理和工程领域，理解作用于物体的各种力对于设计能够承受不同条件的结构和系统至关重要。其中一个重要的概念是周向力，指的是沿圆形物体的周边施加的力。这种力量在涉及旋转机械、圆柱形结构甚至车辆设计的应用中尤为重要。周向力在确保操作期间的稳定性和完整性方面发挥着至关重要的作用。为了说明周向力的重要性，考虑一个简单的旋转轮子的例子。当轮子旋转时，作用于它的力不仅是垂直的，还有水平的。周向力负责维持轮子的旋转，并确保它不会因自身重量或外部负载而崩溃。如果周向力不足，轮子可能会经历变形或失效，从而导致潜在的事故。此外，在工程设计中，理解如何计算和应用周向力对各种结构的安全性和功能性至关重要。例如，在设计一条承载压力流体的管道时，工程师必须考虑作用在管道壁上的周向力。如果这个力超过了材料的强度，就可能导致破裂或泄漏，造成环境危害和经济损失。周向力的概念不仅限于机械应用；它在土木工程中也很相关。例如，在建造桥梁时，工程师必须考虑由于桥梁自身的重量以及它将承载的负载而产生的周向力。适当的计算确保所用材料能够承受这些力量，从而防止结构失效。除了其实际应用，研究周向力还提供了对基本物理原理的深入了解。它与张力、压缩和剪切力等概念有关。理解这些力量在系统内如何相互作用有助于科学家和工程师开发更好的模型，以预测在各种条件下的行为。此外，技术的进步使得对周向力的更精确测量和模拟成为可能。借助计算机辅助设计（CAD）软件和有限元分析（FEA），工程师可以可视化力量如何分布在结构中，从而使他们在设计过程中做出明智的决策。总之，周向力是物理和工程中的基本概念，在各个领域具有深远的影响。从确保旋转机械的安全到优化基础设施设计，理解这种力量对于创造可靠和高效的系统至关重要。随着技术的不断发展，分析和应用周向力的方法无疑会进步，从而推动工程和设计领域的更大创新。