hypoid

简明释义

英[/ˈhaɪpɔɪd/]美[/ˈhaɪpɔɪd/]

adj. [数] 准双曲面的；交错轴齿轮的

英英释义

单词用法

同义词

反义词

例句

1.The teeth on bevel gears can be straight, spiral or hypoid.

锥齿轮的齿可以是直齿、螺旋形或准双曲面。

2.The theory of calculating geometric parameters of pitch cone of curved tooth hypoid gear is investigated in this paper.

本文研究了曲齿准双曲面齿轮分度锥面几何参数计算的原理。

3.The developed system can easily read data from graphs and tables, design hypoid gears, verify tooth strength, do drawings and calculate cutting and machine setting parameters.

该系统能方便完成图表数据检索、齿坯设计、强度校核、绘图、调整卡计算输出。

4.Pressed and welded steel banjo housing, single reduction, hypoid.

冲压，焊接钢班卓琴住房，单减少，双曲线。

5.The vibration of Hypoid gear is main reason of rear axle vibration, the key of reduce rear axle vibration lie in improving gear's processing, assembly quality.

准双曲面齿轮的振动是后桥振动的主要原因，减小后桥振动的关键在于提高齿轮的加工，装配质量。

6.The CNC hypoid cutting machine is a new kind of machine tool, which coordinates all machine movement necessary for gear manufacturing in 6 axes of motion.

螺旋锥齿轮和准双曲面齿轮数控磨齿机是一种新机床，将齿轮加工所需全部运动用六坐标数控来实现。

7.The engineer explained how the hypoid 锥齿轮 design improves the efficiency of the drivetrain.

工程师解释了如何通过<顺>hypoid 锥齿轮设计提高传动系统的效率。

8.In a hypoid 曲轴 system, the gears are positioned at an angle to each other, allowing for smoother operation.

在<顺>hypoid 曲轴系统中，齿轮之间以一定角度排列，从而实现更平稳的操作。

9.The hypoid 齿轮 is commonly used in automotive applications due to its ability to handle high torque.

由于其能够承受高扭矩，hypoid 齿轮在汽车应用中被广泛使用。

10.Understanding the hypoid 齿轮比 is crucial for optimizing vehicle performance.

理解hypoid 齿轮比对于优化车辆性能至关重要。

11.The hypoid 差速器 allows for better handling during turns by distributing power effectively.

hypoid 差速器通过有效分配动力，使转弯时的操控性更好。

作文

In the world of mechanics and engineering, the term hypoid refers to a specific type of gear system that is essential for various applications, particularly in automotive engineering. A hypoid gear is similar to a bevel gear but has a unique design that allows for smoother operation and better load distribution. This feature makes it particularly useful in vehicles where the drive shaft needs to connect to the wheels at an angle. Understanding the mechanics behind hypoid gears can significantly enhance our grasp of how modern vehicles operate. The primary advantage of hypoid gears lies in their ability to provide a more efficient transfer of power compared to traditional gears. The design of a hypoid gear allows for the pinion and the ring gear to be offset from each other, which results in a larger contact area between the teeth. This increased contact area reduces wear and tear, leading to a longer lifespan for the gear system. Additionally, the offset design of hypoid gears enables them to operate more quietly than other types of gears, which is a significant benefit in automotive design where noise reduction is a priority. Moreover, hypoid gears are often used in differential systems of vehicles. The differential is a crucial component that allows the wheels to rotate at different speeds while turning, preventing tire wear and enhancing vehicle stability. By utilizing hypoid gears in this system, engineers can ensure that the torque is distributed evenly across the wheels, improving overall performance and handling. One of the challenges with hypoid gears, however, is the complexity of their manufacturing process. The precise cutting and shaping required to create these gears demand advanced machinery and skilled craftsmanship. This complexity can lead to higher production costs, making hypoid gears more expensive than simpler gear types. Despite this, the benefits they offer in terms of efficiency and durability often outweigh the initial investment, especially in high-performance vehicles where every detail counts. In conclusion, the term hypoid encompasses a vital aspect of mechanical engineering that plays a critical role in the functionality of modern vehicles. From their unique design that enhances power transfer to their application in differential systems, hypoid gears demonstrate the intricate balance between innovation and practicality in engineering. As technology continues to evolve, the significance of hypoid gears will likely grow, paving the way for even more advancements in automotive design and performance. Understanding hypoid gears not only enriches our knowledge of mechanical systems but also highlights the importance of precision and efficiency in engineering practices. Therefore, as we explore the future of automotive technology, the role of hypoid gears will remain a cornerstone of effective design and engineering excellence.

在机械和工程的世界中，术语hypoid指的是一种特定类型的齿轮系统，这在各种应用中至关重要，特别是在汽车工程中。hypoid齿轮类似于锥齿轮，但其独特的设计允许更平滑的操作和更好的负载分配。这一特性使其在驱动轴需要以一定角度连接到车轮的车辆中尤其有用。理解hypoid齿轮背后的机械原理，可以显著增强我们对现代车辆操作方式的理解。 hypoid齿轮的主要优势在于它们能够比传统齿轮提供更高效的动力传输。hypoid齿轮的设计使得小齿轮和大齿轮彼此偏移，从而导致齿之间的接触面积增大。这种增加的接触面积减少了磨损，从而延长了齿轮系统的使用寿命。此外，hypoid齿轮的偏移设计使其比其他类型的齿轮更安静运行，这在汽车设计中是一个重要的好处，因为降噪是优先考虑的事项。 此外，hypoid齿轮常用于车辆的差速器系统。差速器是一个关键组件，它允许车轮在转弯时以不同的速度旋转，从而防止轮胎磨损并增强车辆稳定性。通过在该系统中利用hypoid齿轮，工程师可以确保扭矩均匀分配到车轮上，从而提高整体性能和操控性。 然而，hypoid齿轮面临的一个挑战是其制造过程的复杂性。制造这些齿轮所需的精确切割和成型要求先进的机械设备和熟练的工艺。这种复杂性可能导致生产成本较高，使得hypoid齿轮比更简单的齿轮类型更昂贵。尽管如此，它们在效率和耐用性方面所提供的好处通常超过了初始投资，特别是在高性能车辆中，每个细节都至关重要。 总之，术语hypoid涵盖了机械工程的一个重要方面，在现代车辆的功能中发挥着关键作用。从其增强动力传输的独特设计到在差速器系统中的应用，hypoid齿轮展示了工程中的创新与实用性之间的微妙平衡。随着技术的不断发展，hypoid齿轮的重要性可能会进一步增长，为汽车设计和性能的更多进步铺平道路。理解hypoid齿轮不仅丰富了我们对机械系统的知识，还突显了在工程实践中精确性和效率的重要性。因此，当我们探索汽车技术的未来时，hypoid齿轮的角色将仍然是有效设计和工程卓越的基石。