angular distortion
简明释义
角失真
英英释义
例句
1.To minimize angular distortion 角度失真, we need to adjust the alignment of the components.
为了最小化角度失真,我们需要调整组件的对齐。
2.The engineer noticed significant angular distortion 角度失真 in the structure during the inspection.
工程师在检查过程中注意到结构中存在显著的角度失真。
3.The technician used a laser tool to measure angular distortion 角度失真 in the installation.
技术员使用激光工具测量安装中的角度失真。
4.In 3D modeling, angular distortion 角度失真 can lead to unrealistic representations.
在3D建模中,角度失真可能导致不现实的表现。
5.The manufacturing process was altered to reduce angular distortion 角度失真 in the final product.
制造过程被改变,以减少最终产品中的角度失真。
作文
In the realm of engineering and design, the term angular distortion refers to the deviation from the intended angles in a structure or component. This phenomenon can occur due to various factors such as thermal expansion, material fatigue, or improper assembly techniques. Understanding angular distortion is crucial for engineers and architects, as it can significantly affect the integrity and functionality of a structure. For instance, when components are welded together, the heat generated during the welding process can cause the materials to expand. Upon cooling, this may lead to an uneven contraction, resulting in angular distortion. Such distortions can compromise the alignment of structural elements, leading to potential failures or safety hazards.Moreover, angular distortion is not limited to welding processes; it can also arise in various manufacturing processes such as casting, machining, and 3D printing. In casting, for example, if the cooling rate is uneven, certain parts of the cast can shrink at different rates, causing misalignments. Similarly, in machining, if excessive forces are applied during cutting, it can lead to warping and angular distortion of the workpiece.To mitigate the effects of angular distortion, engineers often employ several strategies. One common approach is to carefully control the temperature during welding or other heat-intensive processes. Preheating materials before welding can help reduce the temperature gradient and minimize the risk of distortion. Additionally, using jigs and fixtures can ensure that components remain aligned during assembly, which further reduces the likelihood of angular distortion.Another important aspect is the selection of materials. Engineers may choose materials that have lower thermal expansion coefficients or higher resistance to deformation under stress. By understanding the properties of different materials, they can better predict how they will behave under various conditions, thereby reducing the chances of angular distortion occurring.Furthermore, advanced simulation software has become an invaluable tool in modern engineering. These programs allow engineers to model and predict how a design will react under different stresses and temperatures. By simulating potential scenarios, they can identify areas where angular distortion might occur and make necessary adjustments before production begins.In conclusion, angular distortion is a critical factor that engineers must consider during the design and manufacturing processes. Its implications can range from minor aesthetic issues to severe structural failures. By understanding the causes and implementing effective strategies to manage it, professionals in the field can ensure the longevity and safety of their constructions. The continuous development of technology and materials science will undoubtedly provide further insights into minimizing angular distortion and enhancing overall structural integrity.
在工程和设计领域,术语角度畸变指的是结构或组件中与预期角度的偏差。这种现象可能由于多种因素引起,例如热膨胀、材料疲劳或组装技术不当。理解角度畸变对工程师和建筑师至关重要,因为它可以显著影响结构的完整性和功能。例如,当组件焊接在一起时,焊接过程中产生的热量会导致材料膨胀。冷却后,这可能导致不均匀收缩,从而导致角度畸变。这种畸变可能会妨碍结构元素的对齐,导致潜在的故障或安全隐患。此外,角度畸变不仅限于焊接过程;它还可以在铸造、机械加工和3D打印等各种制造过程中发生。例如,在铸造中,如果冷却速度不均匀,铸件的某些部分可能以不同的速度收缩,从而导致错位。同样,在机械加工中,如果在切割过程中施加过大的力,就可能导致工件翘曲和角度畸变。为了减轻角度畸变的影响,工程师通常采用几种策略。一个常见的方法是在焊接或其他高温过程期间仔细控制温度。焊接前对材料进行预热可以帮助减少温度梯度,从而降低畸变的风险。此外,使用夹具和固定装置可以确保组件在组装过程中保持对齐,这进一步减少了角度畸变的可能性。另一个重要方面是材料的选择。工程师可能会选择具有较低热膨胀系数或更高抗变形能力的材料。通过了解不同材料的特性,他们可以更好地预测它们在各种条件下的表现,从而减少角度畸变发生的机会。此外,先进的模拟软件已成为现代工程中的一项宝贵工具。这些程序允许工程师模拟和预测设计在不同应力和温度下的反应。通过模拟潜在场景,他们可以识别可能发生角度畸变的区域,并在生产开始之前进行必要的调整。总之,角度畸变是工程师在设计和制造过程中必须考虑的一个关键因素。其影响范围从轻微的美观问题到严重的结构故障。通过理解原因并实施有效的管理策略,专业人员可以确保其建筑的耐久性和安全性。科技和材料科学的持续发展无疑会为减少角度畸变并增强整体结构完整性提供进一步的见解。
