radial pitch variation

简明释义

沿半径变化的螺距

英英释义

例句

1.The technician adjusted the settings to compensate for the radial pitch variation 径向间距变化 observed in the test results.

技术员调整了设置，以补偿测试结果中观察到的径向间距变化。

2.In our latest study, we found that radial pitch variation 径向间距变化 can lead to increased vibration levels in rotating machinery.

在我们最新的研究中，我们发现径向间距变化会导致旋转机械中振动水平的增加。

3.The design specifications included tolerances for radial pitch variation 径向间距变化 to minimize wear on the bearings.

设计规范中包括了对径向间距变化的公差，以最小化轴承的磨损。

4.To ensure accuracy, we must measure the radial pitch variation 径向间距变化 during the manufacturing process.

为了确保准确性，我们必须在制造过程中测量径向间距变化。

5.The engineer noted that the radial pitch variation 径向间距变化 in the gear teeth could affect the overall performance of the mechanism.

工程师指出，齿轮齿的径向间距变化可能会影响机制的整体性能。

作文

In the realm of mechanical engineering and design, precision is paramount. One of the key concepts that engineers must understand is the concept of radial pitch variation, which refers to the differences in spacing between features along a radial line from a central axis. This variation can significantly impact the performance and functionality of machinery, particularly in rotating systems like gears, turbines, and propellers.To better understand radial pitch variation, let’s consider its application in gear design. Gears are fundamental components in many machines, and their efficiency depends heavily on how well they mesh with one another. If the pitch—the distance between corresponding points on adjacent teeth—is not consistent, it can lead to increased wear, noise, and even failure of the system. Therefore, engineers must carefully calculate and control radial pitch variation to ensure that the gears operate smoothly and efficiently.Moreover, radial pitch variation is not only relevant in gears but also plays a crucial role in the design of other rotational components. For instance, in the aerospace industry, the blades of a turbine must be designed with precise radial pitch variation to optimize airflow and maximize thrust. Any deviation from the intended design can result in reduced performance and increased fuel consumption, which are critical factors in aviation.In addition to mechanical applications, understanding radial pitch variation is essential in fields such as robotics and automotive engineering. In robotic arms, for example, the joints must have accurately calculated radial pitch variation to ensure smooth and precise movements. Similarly, in automobiles, the alignment of wheels and axles requires careful consideration of radial pitch variation to enhance stability and handling.The importance of monitoring and adjusting radial pitch variation cannot be overstated. Engineers often utilize advanced tools and technologies, such as computer-aided design (CAD) software and simulation models, to analyze and predict how variations will affect overall performance. By doing so, they can make informed decisions during the design process, leading to improved product reliability and longevity.In conclusion, radial pitch variation is a critical concept in engineering that impacts the performance of various mechanical systems. Whether it is in gear design, turbine blade optimization, or robotic movement, controlling this variation is essential for achieving desired outcomes. As technology continues to advance, the methods for analyzing and managing radial pitch variation will also evolve, paving the way for more efficient and reliable engineering solutions. Understanding this concept is not just an academic exercise; it is a vital part of creating systems that function effectively in the real world.

在机械工程和设计领域，精度至关重要。工程师必须理解的关键概念之一是径向节距变化，它指的是沿着从中心轴线发出的径向线之间特征的间距差异。这种变化会显著影响机器的性能和功能，特别是在齿轮、涡轮和螺旋桨等旋转系统中。 为了更好地理解径向节距变化，让我们考虑其在齿轮设计中的应用。齿轮是许多机器的基本组成部分，它们的效率在很大程度上取决于相互啮合的良好程度。如果节距——即相邻齿上相应点之间的距离——不一致，则可能导致磨损增加、噪音增大，甚至系统故障。因此，工程师必须仔细计算和控制径向节距变化，以确保齿轮平稳高效地运行。此外，径向节距变化不仅在齿轮中相关，在其他旋转组件的设计中也起着至关重要的作用。例如，在航空航天工业中，涡轮的叶片必须以精确的径向节距变化进行设计，以优化气流并最大化推力。任何偏离预期设计的情况都可能导致性能下降和燃料消耗增加，这在航空中是至关重要的因素。除了机械应用之外，了解径向节距变化在机器人技术和汽车工程等领域也是必不可少的。在机器人手臂中，例如，关节必须具有准确计算的径向节距变化，以确保平稳和精确的运动。同样，在汽车中，车轮和车轴的对齐需要仔细考虑径向节距变化，以增强稳定性和操控性。监测和调整径向节距变化的重要性不容小觑。工程师们通常利用先进的工具和技术，如计算机辅助设计（CAD）软件和仿真模型，来分析和预测变化将如何影响整体性能。通过这样做，他们可以在设计过程中做出明智的决策，从而提高产品的可靠性和耐用性。总之，径向节距变化是一个在工程中至关重要的概念，影响着各种机械系统的性能。无论是在齿轮设计、涡轮叶片优化还是机器人运动中，控制这种变化对于实现预期结果至关重要。随着技术的不断进步，分析和管理径向节距变化的方法也将不断演变，为更高效、更可靠的工程解决方案铺平道路。理解这一概念不仅仅是学术练习；它是创造在现实世界中有效运作的系统的重要组成部分。