deflection distortion

简明释义

偏转失真

英英释义

例句

1.The engineer noted that the bridge's design needed to account for deflection distortion 挠度失真 caused by heavy traffic.

工程师指出，桥梁的设计需要考虑由于重型交通造成的deflection distortion 挠度失真。

2.The report highlighted how deflection distortion 挠度失真 affected the overall stability of the structure.

报告强调了deflection distortion 挠度失真如何影响结构的整体稳定性。

3.The architect was concerned about the deflection distortion 挠度失真 that could occur during strong winds.

建筑师担心在强风中可能发生的deflection distortion 挠度失真。

4.In structural analysis, deflection distortion 挠度失真 can lead to unexpected failures if not properly managed.

在结构分析中，如果没有妥善管理，deflection distortion 挠度失真可能导致意外故障。

5.To minimize deflection distortion 挠度失真, we reinforced the beams in the new building design.

为了最小化deflection distortion 挠度失真，我们在新建筑设计中加固了梁。

作文

In the field of engineering and materials science, understanding the concepts of stress and strain is crucial for designing structures that can withstand various loads. One important phenomenon that engineers must consider is deflection distortion, which refers to the deformation of a structural element when subjected to external forces. This term encompasses both the bending of materials and the resultant changes in shape that occur under load. The implications of deflection distortion can be significant, affecting not only the performance of the structure but also its safety and longevity.When a beam or a similar structural component is loaded, it experiences a force that causes it to bend. This bending is what we refer to as deflection distortion. The amount of deflection experienced by the beam depends on several factors, including the material properties, the geometry of the beam, and the magnitude of the applied load. Engineers use mathematical models to predict how much a beam will deflect under a given load, allowing them to design structures that remain within acceptable limits of deformation.One common application of understanding deflection distortion is in the construction of bridges. Bridges are designed to carry heavy loads, such as vehicles and pedestrians, without excessive bending or deformation. If a bridge experiences too much deflection distortion, it could lead to structural failure, posing a risk to public safety. Therefore, engineers must carefully analyze the expected loads and design the bridge to minimize deflection distortion, ensuring it remains stable and safe throughout its lifespan.In addition to bridges, deflection distortion is also a critical consideration in the design of buildings, towers, and other infrastructure. For instance, tall buildings must be designed to withstand wind loads, which can cause significant lateral deflection. Engineers employ advanced materials and construction techniques to mitigate the effects of deflection distortion, ensuring that buildings can sway without compromising their structural integrity.Moreover, deflection distortion is not limited to large structures. It can also impact smaller components, such as beams in furniture or frames in machinery. For example, a poorly designed chair may experience excessive deflection distortion when someone sits on it, leading to discomfort or even breakage. Thus, understanding this concept is essential for product designers and manufacturers who aim to create durable and functional products.In conclusion, deflection distortion plays a vital role in engineering and design. By understanding how materials deform under load, engineers can create safer and more efficient structures. Whether it is a bridge, a building, or a piece of furniture, considering deflection distortion is essential for ensuring the longevity and safety of the design. As technology advances, the tools and methods for analyzing deflection distortion continue to improve, enabling engineers to push the boundaries of what is possible in construction and design.

在工程和材料科学领域，理解应力和应变的概念对于设计能够承受各种载荷的结构至关重要。工程师必须考虑的一个重要现象是挠度畸变，它指的是当结构元件受到外部力时的变形。这个术语涵盖了材料的弯曲以及在负载下发生的形状变化。挠度畸变的影响可能是显著的，不仅影响结构的性能，还影响其安全性和耐久性。当梁或类似的结构组件受到负载时，它会经历一种力，这种力使其弯曲。这种弯曲就是我们所说的挠度畸变。梁所经历的挠度量取决于多个因素，包括材料特性、梁的几何形状和施加负载的大小。工程师使用数学模型来预测在给定负载下梁将弯曲多少，从而使他们能够设计出保持在可接受的变形限制内的结构。理解挠度畸变的一个常见应用是在桥梁的建设中。桥梁被设计用来承受重载，例如车辆和行人，而不会过度弯曲或变形。如果一座桥经历了过多的挠度畸变，可能导致结构失效，危及公共安全。因此，工程师必须仔细分析预期负载，并设计桥梁以最小化挠度畸变，确保它在整个生命周期内保持稳定和安全。除了桥梁，挠度畸变也是建筑物、塔楼和其他基础设施设计中的关键考虑因素。例如，高层建筑必须设计成能够承受风载荷，这可能导致显著的横向挠度。工程师采用先进的材料和施工技术来减轻挠度畸变的影响，确保建筑在摇摆时不会妨碍其结构完整性。此外，挠度畸变不仅限于大型结构。它也可能影响较小的组件，例如家具中的梁或机械中的框架。例如，一个设计不良的椅子在有人坐下时可能经历过度的挠度畸变，导致不适甚至断裂。因此，理解这一概念对于旨在创造耐用和功能性产品的产品设计师和制造商至关重要。总之，挠度畸变在工程和设计中发挥着至关重要的作用。通过理解材料在负载下如何变形，工程师可以创造出更安全、更高效的结构。无论是桥梁、建筑物还是家具，考虑挠度畸变对于确保设计的耐久性和安全性至关重要。随着技术的进步，分析挠度畸变的工具和方法不断改进，使工程师能够突破建筑和设计的可能性界限。