deflexion

简明释义

英[dɪˈflekʃən]美[dɪˈflekʃən]

n. 偏转，偏斜；挠曲（等于 deflection）

英英释义

单词用法

同义词

反义词

例句

1.This paper discussing the mirror photo method and finding the solution deflexion of the plates through mirrir photo method under the concentrate force.

本又讨论了映象法，并利用映象法求解了板在集中载荷作用下的挠度。

2.When polarization light transits EO that is put on voltage, its polarization orientation has a deflexion.

当极化光通过加有电压的电光晶体时，光的极化方向发生偏转，偏转的角度正比于电压。

3.These people although "sleeps disagreement eye", but had closed approach as a result of partial eyelid, black eyeball always is a side that deflexion is shutting faze, show white share only.

这些人虽然“睡不合眼”，但由于部分眼皮已经闭拢，黑眼珠总是偏转在闭扰的一侧，只露出眼白部分。

4.Result Asymmetric inlet velocity profile deflexion could increase the area of low shear stress and the gradient of shear stress.

结论不对称入口速度剖面可能是诱发动脉粥样硬化发生的一个危险因子。

5.This article expatiates the lead-foot-line reciprocation method and its usages from the two sides of cathode lead-foot joint reciprocation and deflexion loop down-lead reciprocation.

从阴极引脚接点互换和偏转线圈引线互换两个方面对“引脚线互换法”及其用法进行了阐述。

6.The velocity field and shear rate distribution are reduced and uniform along with the proper increase of slip length. The die swell and the interface deflexion phenomenon will be reduced effectively.

适当增加流道的长度，可以减小胶料出口处的速度场、剪切速率场的集中程度并使之趋于均匀，能够有效降低挤出胀大和模外熔体偏转流动现象。

7.The velocity field and shear rate distribution are reduced and uniform along with the proper increase of slip length. The die swell and the interface deflexion phenomenon will be reduced effectively.

适当增加流道的长度，可以减小胶料出口处的速度场、剪切速率场的集中程度并使之趋于均匀，能够有效降低挤出胀大和模外熔体偏转流动现象。

8.The response of mechanism deflexion is slowly, which velocity and precision are confinement each other.

机械偏转响应慢，偏转速度与控制精度相互制约。

9.The engineer measured the deflexion 偏斜 of the beam under load to ensure it met safety standards.

工程师测量了梁在负载下的deflexion 偏斜，以确保其符合安全标准。

10.In optics, the deflexion 偏斜 of light rays can be observed when they pass through a prism.

在光学中，当光线通过棱镜时，可以观察到光线的deflexion 偏斜。

11.The study focused on the deflexion 偏斜 of the cantilever under various weight conditions.

该研究集中于在不同重量条件下悬臂的deflexion 偏斜。

12.A significant deflexion 偏斜 in the pipeline could lead to serious operational issues.

管道的显著deflexion 偏斜可能导致严重的操作问题。

13.The deflexion 偏斜 of the road surface was measured to plan for repairs.

测量了路面deflexion 偏斜以计划维修工作。

作文

In the realm of physics and engineering, the concept of deflexion plays a crucial role in understanding how structures respond to various forces. Deflexion refers to the displacement or bending of a beam or structural element when subjected to external loads. This phenomenon is particularly important in the design and analysis of bridges, buildings, and other constructions where safety and stability are paramount. For instance, when a load is applied to the center of a beam, it will naturally bend downwards, resulting in a deflexion that engineers must account for to ensure that the structure can withstand the forces without failing. The study of deflexion involves various mathematical principles and physical laws, such as Euler-Bernoulli beam theory, which provides a framework for calculating the amount of bending that occurs under specific conditions. Engineers use this theory to predict how much a beam will bend when subjected to loads, allowing them to design structures that are both functional and safe. The ability to accurately calculate deflexion is essential because excessive bending can lead to structural failure, posing risks to safety and integrity. Moreover, deflexion is not just limited to beams; it can also be observed in other materials and structures, including arches and cables. For example, in suspension bridges, the cables experience deflexion as they support the weight of the bridge deck. Understanding how these elements behave under load is vital for ensuring that the bridge remains stable and safe for use. In practical applications, engineers often utilize software tools that simulate deflexion and other structural behaviors. These tools allow for the visualization of how a structure will respond to various loads and conditions, enabling engineers to make informed decisions during the design process. By analyzing the deflexion of a structure, they can optimize materials and shapes to enhance performance while minimizing costs. Furthermore, the implications of deflexion extend beyond engineering into fields such as architecture and construction management. Architects must consider deflexion when designing aesthetically pleasing structures that also meet safety standards. For instance, the iconic Sydney Opera House features unique shapes and forms that required careful consideration of deflexion to ensure its stability and durability. In conclusion, deflexion is a fundamental concept in the study of structures and materials, encompassing the bending and displacement that occur under load. Its significance in engineering cannot be overstated, as it directly impacts the safety and functionality of various constructions. By understanding and accurately predicting deflexion, engineers and architects can create innovative designs that not only meet aesthetic desires but also adhere to strict safety regulations. As technology advances and our understanding of materials improves, the study of deflexion will continue to evolve, leading to even more resilient and efficient structures in the future.

在物理和工程领域，deflexion的概念在理解结构如何响应各种力方面起着至关重要的作用。Deflexion指的是当结构元件受到外部载荷时的位移或弯曲。这一现象在桥梁、建筑和其他建筑物的设计与分析中尤为重要，因为安全性和稳定性是首要考虑的因素。例如，当载荷施加到梁的中心时，它自然会向下弯曲，导致deflexion，工程师必须对此进行考虑，以确保结构能够承受这些力量而不发生故障。 Deflexion的研究涉及各种数学原理和物理法则，例如欧拉-伯努利梁理论，该理论提供了在特定条件下计算弯曲程度的框架。工程师利用这一理论预测梁在载荷作用下的弯曲程度，从而设计出既功能性又安全的结构。准确计算deflexion的能力至关重要，因为过度的弯曲可能导致结构失效，带来安全和完整性风险。 此外，deflexion不仅限于梁；在其他材料和结构中也可以观察到，如拱和电缆。例如，在悬索桥中，电缆在支撑桥面重量时会经历deflexion。理解这些元素在载荷下的行为对确保桥梁的稳定性和安全性至关重要。 在实际应用中，工程师通常利用模拟软件工具来模拟deflexion和其他结构行为。这些工具允许可视化结构在各种载荷和条件下的响应，使工程师能够在设计过程中做出明智的决策。通过分析结构的deflexion，他们可以优化材料和形状，以提高性能，同时降低成本。 此外，deflexion的影响超越了工程，延伸到建筑和施工管理等领域。建筑师在设计美观的同时也必须考虑deflexion以满足安全标准。例如，标志性的悉尼歌剧院具有独特的形状和形式，需要仔细考虑deflexion以确保其稳定性和耐用性。 总之，deflexion是结构和材料研究中的一个基本概念，涵盖了在载荷下发生的弯曲和位移。它在工程中的重要性不容小觑，因为它直接影响到各种建筑物的安全性和功能性。通过理解和准确预测deflexion，工程师和建筑师可以创造出既能满足美学需求，又能遵循严格安全规定的创新设计。随着技术的进步和我们对材料的理解不断提高，deflexion的研究将继续发展，未来将导致更具韧性和高效的结构。