rivet in tension

简明释义

受拉铆钉

英英释义

例句

1.In high-stress environments, a rivet in tension can fail if not properly maintained.

在高应力环境中，如果维护不当，受拉铆钉可能会失效。

2.To ensure safety, it is crucial to monitor the rivet in tension regularly.

为了确保安全，定期监测受拉铆钉是至关重要的。

3.The construction team had to replace a rivet in tension that was improperly installed.

施工队不得不更换一个安装不当的受拉铆钉。

4.During the inspection, we noticed that one rivet in tension was starting to show signs of fatigue.

在检查过程中，我们注意到一个受拉铆钉开始出现疲劳迹象。

5.The engineer explained that the load on the bridge caused the rivet in tension to bear more weight than anticipated.

工程师解释说，桥上的负载导致受拉铆钉承受的重量超出了预期。

作文

In the world of engineering and construction, understanding the various components that contribute to the structural integrity of a building or machine is crucial. One such component that plays a significant role in joining materials together is the rivet. A rivet is a mechanical fastener that is used to hold two or more pieces of material together. While rivets can be used in various ways, one of the most critical applications is when they are subjected to forces that create tension. This brings us to the term rivet in tension, which refers to a specific condition where the rivet is under tensile stress due to external loads. When a rivet is installed, it is typically placed through pre-drilled holes in the materials being joined. Once positioned, the rivet is deformed at its head, creating a permanent connection. However, when the connected materials experience pulling forces, the rivet must resist these forces to maintain the integrity of the joint. This situation is what we refer to as rivet in tension (铆钉受拉). Understanding this concept is essential for engineers, as it influences the design and selection of rivets in various applications.For example, in the aerospace industry, the use of rivets is prevalent in the assembly of aircraft structures. Aircraft are subjected to various forces during flight, including lift, drag, and turbulence. When these forces act on the aircraft, certain components may experience tension. Engineers must ensure that the rivets used in these applications can withstand the tensile forces without failing. If a rivet fails under tension, it could lead to catastrophic consequences, such as structural failure or loss of control of the aircraft.To prevent such failures, engineers conduct thorough analyses of the materials and rivets used in construction. They consider factors such as the material properties, the size of the rivet, and the expected loads the structure will encounter. By doing so, they can select rivets that are appropriately rated for the required tensile strength. This is where the concept of rivet in tension becomes vital in the design process.Moreover, understanding the behavior of rivets under tension also allows engineers to predict how joints will perform over time. For instance, repeated loading and unloading cycles can lead to fatigue in the rivet, which may eventually compromise its ability to hold the materials together. Engineers must account for this potential issue by selecting rivets that can endure such conditions, ensuring that the joint remains secure throughout its lifespan.In conclusion, the term rivet in tension (铆钉受拉) encapsulates a critical aspect of engineering design and analysis. It highlights the importance of understanding how rivets behave under tensile forces and the implications this has for structural integrity. Whether in aerospace, automotive, or civil engineering, recognizing the significance of rivets in tension is essential for creating safe and reliable structures. As technology advances and new materials are developed, engineers will continue to refine their understanding of these concepts to enhance the safety and efficiency of their designs.

在工程和建筑的世界中，理解构成建筑物或机器结构完整性的各种组件至关重要。其中一个在连接材料中起重要作用的组件是铆钉。铆钉是一种机械紧固件，用于将两个或多个材料件固定在一起。虽然铆钉可以以多种方式使用，但其中一个最关键的应用是当它们受到产生拉力的外力时。这使我们提到了“rivet in tension”这个术语，它指的是铆钉由于外部载荷而承受拉应力的特定状态。当铆钉安装时，它通常被放置在被连接材料的预钻孔中。一旦就位，铆钉的头部会变形，从而形成永久连接。然而，当连接的材料经历拉力时，铆钉必须抵抗这些力，以维持接头的完整性。这种情况就是我们所称的rivet in tension（铆钉受拉）。理解这一概念对工程师至关重要，因为它影响着在各种应用中铆钉的设计和选择。例如，在航空航天工业中，铆钉在飞机结构的组装中被广泛使用。飞机在飞行中会受到各种力量的影响，包括升力、阻力和湍流。当这些力量作用于飞机时，某些组件可能会经历拉力。工程师必须确保在这些应用中使用的铆钉能够承受拉力，而不会失效。如果铆钉在拉力下失效，可能会导致灾难性的后果，如结构失效或飞机失控。为了防止此类失效，工程师对所使用的材料和铆钉进行彻底分析。他们考虑材料的特性、铆钉的大小以及结构将遇到的预期载荷等因素。通过这样做，他们可以选择适合所需拉伸强度的铆钉。这就是rivet in tension在设计过程中的重要性所在。此外，理解铆钉在拉力下的行为还使工程师能够预测接头在时间上的表现。例如，反复的加载和卸载循环可能会导致铆钉疲劳，这最终可能会危及其保持材料连接的能力。工程师必须考虑这一潜在问题，选择能够承受这种条件的铆钉，确保接头在整个生命周期内保持安全。总之，术语rivet in tension（铆钉受拉）概括了工程设计和分析的一个关键方面。它突出了理解铆钉在拉力下的行为及其对结构完整性的影响的重要性。无论是在航空航天、汽车还是土木工程中，认识到铆钉在拉力下的重要性对创建安全可靠的结构至关重要。随着技术的进步和新材料的发展，工程师将继续完善对这些概念的理解，以提高他们设计的安全性和效率。