angular misalignment

简明释义

角偏差

英英释义

Angular misalignment refers to a condition where two or more components are not aligned at the correct angle relative to each other, which can lead to inefficiencies or mechanical failure.

角度失调是指两个或多个组件之间的角度未正确对齐,这可能导致效率低下或机械故障。

例句

1.An angular misalignment 角度不对齐 in the wheel alignment can cause uneven tire wear.

车轮对齐中的angular misalignment 角度不对齐会导致轮胎磨损不均。

2.The technician adjusted the lens to correct the angular misalignment 角度不对齐 that was causing blurry images.

技术员调整镜头以修正造成模糊图像的angular misalignment 角度不对齐

3.The architect noted an angular misalignment 角度不对齐 in the building's facade that needed immediate attention.

建筑师注意到建筑外立面存在angular misalignment 角度不对齐,需要立即处理。

4.The engineers discovered an angular misalignment 角度不对齐 in the robot's arm, which affected its precision.

工程师发现机器臂存在一个angular misalignment 角度不对齐,这影响了其精确度。

5.During the assembly process, a minor angular misalignment 角度不对齐 can lead to significant performance issues.

在组装过程中,轻微的angular misalignment 角度不对齐可能会导致显著的性能问题。

作文

In the realm of engineering and mechanics, precision is paramount. One of the critical factors that can affect the performance of machines and structures is the phenomenon known as angular misalignment. This term refers to the deviation of an object's alignment from its intended angle. Such misalignment can occur in various contexts, including machinery, structural components, and even in everyday applications like furniture assembly. Understanding angular misalignment is essential for maintaining efficiency and preventing damage in mechanical systems.To illustrate this concept, consider a simple example of a rotating shaft in a motor. If the shaft is not aligned correctly, it can lead to vibrations, excessive wear, and ultimately, failure of the motor. The misalignment can be caused by improper installation, wear and tear over time, or external forces acting on the system. This is where the importance of recognizing angular misalignment comes into play. Engineers must regularly check and adjust the alignment of components to ensure optimal performance.Moreover, angular misalignment is not limited to mechanical systems. In civil engineering, when constructing buildings or bridges, even a slight misalignment in the angles of beams or supports can lead to significant structural issues. For instance, if the angles are off, the weight distribution may become uneven, leading to potential failures under load. Therefore, engineers use precise tools and methods to measure and correct any misalignment during construction.In addition to engineering applications, angular misalignment can also be observed in more mundane situations, such as when assembling furniture. If the legs of a table are not attached at the correct angles, the table may wobble or be unstable. This misalignment can often be corrected by adjusting the screws or using shims to achieve the desired angle. Such simple adjustments highlight how angular misalignment can impact daily life and functionality.Furthermore, the implications of angular misalignment extend beyond immediate mechanical failure. In industries where safety is a concern, such as aerospace or automotive, even minor misalignments can lead to catastrophic consequences. For example, in aircraft design, precise alignment of components is crucial for safe operation. Any deviation can result in compromised aerodynamics or control issues, potentially endangering lives.In conclusion, angular misalignment is a significant factor in various fields, from engineering to everyday life. Its effects can range from minor inconveniences, like a wobbly table, to severe consequences in critical systems, such as aircraft or industrial machinery. Understanding and addressing angular misalignment is essential for ensuring the efficiency, safety, and longevity of mechanical systems. As technology advances, the tools and methods for measuring and correcting misalignment continue to improve, allowing for greater precision and reliability in engineering practices. Ultimately, being aware of angular misalignment and its implications can lead to better designs, safer operations, and more effective problem-solving in both professional and personal contexts.

在工程和机械领域,精确性至关重要。影响机器和结构性能的关键因素之一是被称为角度不对齐的现象。这个术语指的是物体的对齐偏离其预期角度。这种不对齐可以在各种环境中发生,包括机械、结构组件,甚至在日常应用如家具组装中。理解角度不对齐对于维护效率和防止机械系统的损坏至关重要。为了说明这一概念,考虑一个简单的例子:电机中的旋转轴。如果轴没有正确对齐,可能会导致振动、过度磨损,最终导致电机故障。这种不对齐可能是由于安装不当、随时间推移的磨损或外力作用于系统而造成的。这就是认识角度不对齐重要性的所在。工程师必须定期检查和调整组件的对齐,以确保最佳性能。此外,角度不对齐并不仅限于机械系统。在土木工程中,在建造建筑物或桥梁时,即使是梁或支撑的角度稍有不对齐,也可能导致重大的结构问题。例如,如果角度不正确,重量分布可能变得不均匀,导致在负载下潜在的故障。因此,工程师使用精确的工具和方法在施工过程中测量和纠正任何不对齐。除了工程应用,角度不对齐也可以在更平凡的情况下观察到,例如在组装家具时。如果桌子的腿没有以正确的角度连接,桌子可能会摇晃或不稳定。这种不对齐通常可以通过调整螺丝或使用垫片来实现所需的角度,从而进行纠正。这些简单的调整突显了角度不对齐如何影响日常生活和功能。此外,角度不对齐的影响超出了直接的机械故障。在安全性受到关注的行业,如航空航天或汽车,即使是微小的不对齐也可能导致灾难性后果。例如,在飞机设计中,组件的精确对齐对安全操作至关重要。任何偏差都可能导致空气动力学或控制问题,潜在地危及生命。总之,角度不对齐是各个领域的重要因素,从工程到日常生活。它的影响范围从轻微的不便(如摇晃的桌子)到关键系统(如飞机或工业机械)的严重后果。理解和解决角度不对齐对于确保机械系统的效率、安全和耐用性至关重要。随着技术的进步,测量和纠正不对齐的工具和方法不断改进,使工程实践中的精度和可靠性得到提升。最终,意识到角度不对齐及其影响可以在专业和个人环境中促进更好的设计、更安全的操作和更有效的问题解决。