tangential at bore

简明释义

与孔相切的方向

英英释义

例句

1.To fix the alignment, the technician had to adjust the components that were tangential at bore.

为了修复对齐，技术员必须调整那些在孔的切线方向的组件。

2.During the inspection, the technician found that the pipe was tangential at bore, leading to potential leaks.

在检查过程中，技术员发现管道在孔的切线方向存在问题，可能导致漏水。

3.The report highlighted how the tangential at bore issue affected the overall performance of the machine.

报告强调了孔的切线方向问题如何影响机器的整体性能。

4.When designing the part, the designer ensured that all features were not tangential at bore to avoid structural weaknesses.

在设计零件时，设计师确保所有特征都不是孔的切线方向，以避免结构弱点。

5.The engineer noted that the drill was tangential at bore, which meant it was cutting at an angle rather than straight down.

工程师注意到钻头在孔的切线方向切割，这意味着它是以一个角度而不是垂直向下切割。

作文

In the realm of engineering and design, precision is paramount. Engineers often encounter various challenges that require innovative solutions. One such challenge involves understanding the relationship between different components, especially when they interact at specific angles or points. A term that often arises in this context is tangential at bore, which refers to the direction of a force or line that is tangent to a circular path at the point where it intersects the bore or hole of a component. This concept is crucial for ensuring that mechanical parts function smoothly and efficiently.Understanding tangential at bore requires a grasp of basic geometry and physics. When a force is applied to an object, it can create different types of motion depending on the angle at which it is applied. For instance, if a force is directed along the radius of a circle, it will pull the object toward the center. Conversely, if the force is applied tangentially, it will cause the object to move along the circumference of the circle without pulling it inward. This distinction is vital in applications such as rotating machinery, where the alignment of components affects overall performance.Consider a scenario in which an engineer is designing a rotating shaft with a series of bearings. The bearings are meant to support the shaft while allowing it to spin freely. If the forces acting on the bearings are not aligned properly, it could lead to excessive wear and tear, resulting in mechanical failure. By analyzing the forces and ensuring that they are tangential at bore, the engineer can optimize the design to minimize friction and prolong the life of the bearings.Furthermore, the concept of tangential at bore is not limited to mechanical engineering. It also finds applications in fields such as architecture and structural engineering. For example, when designing arches or domes, engineers must consider the forces acting on these structures. By ensuring that the weight is distributed in a way that is tangential at bore, they can create more stable and resilient designs. This principle helps in preventing structural failures and enhances the longevity of buildings.In addition to its practical applications, the idea of tangential at bore serves as a metaphor for approaching problems in life. Just as engineers must consider the angles and forces at play in their designs, individuals must also evaluate the various factors influencing their decisions. Taking a tangential approach can sometimes yield better results than a direct one, allowing for creativity and flexibility in problem-solving.In conclusion, the term tangential at bore encapsulates a fundamental principle in engineering and design. It highlights the importance of understanding how forces interact with components and the implications of these interactions on functionality and stability. Whether in the context of mechanical systems or broader life challenges, recognizing the significance of angles and directions can lead to more effective solutions. As we continue to innovate and push the boundaries of technology, the principles underlying tangential at bore will remain essential in guiding our efforts toward excellence and efficiency.

在工程和设计领域，精确度至关重要。工程师们经常面临各种挑战，需要创新的解决方案。其中一个挑战涉及理解不同组件之间的关系，特别是当它们在特定角度或点上相互作用时。一个常常出现的术语是tangential at bore，它指的是在与组件的孔或孔相交的点上，力或线的方向与圆形路径的切线方向。这一概念对于确保机械部件平稳高效地运作至关重要。理解tangential at bore需要掌握基本的几何和物理知识。当力施加到物体上时，根据施加的角度，它可以产生不同类型的运动。例如，如果力量沿着圆的半径方向施加，它将把物体拉向中心。相反，如果力量是切向施加的，它将使物体沿着圆周移动，而不会向内拉动。这一区别在旋转机械等应用中至关重要，因为组件的对齐会影响整体性能。考虑一个工程师设计旋转轴及一系列轴承的场景。轴承旨在支撑轴，同时允许其自由旋转。如果施加在轴承上的力没有正确对齐，可能会导致过度磨损，从而导致机械故障。通过分析这些力并确保它们是tangential at bore，工程师可以优化设计，以最小化摩擦并延长轴承的使用寿命。此外，tangential at bore的概念不仅限于机械工程。它还在建筑和结构工程等领域中得到了应用。例如，在设计拱门或穹顶时，工程师必须考虑施加在这些结构上的力量。通过确保重量以tangential at bore的方式分布，他们可以创建更稳定和更具韧性的设计。这一原则有助于防止结构故障，并增强建筑物的耐久性。除了其实际应用外，tangential at bore的概念也可以作为生活中解决问题的一种隐喻。正如工程师必须考虑其设计中作用的角度和力量一样，个人在评估影响他们决策的各种因素时也必须进行考虑。有时采取切向的方法可能比直接的方法产生更好的结果，允许在解决问题时展现创造力和灵活性。总之，术语tangential at bore概括了工程和设计中的基本原则。它强调了理解力量如何与组件相互作用的重要性，以及这些相互作用对功能性和稳定性的影响。无论是在机械系统的背景下，还是在更广泛的生活挑战中，认识到角度和方向的重要性都可以导致更有效的解决方案。随着我们继续创新并推动技术的边界，支撑tangential at bore的原则将继续在指导我们追求卓越和效率的努力中发挥重要作用。