conicity

简明释义

英[kɒˈnɪsɪti]美[koʊˈnɪsɪti]

n. 锥度，圆锥度；锥形

英英释义

单词用法

同义词

反义词

例句

1.The effects of technique parameters, cooling cavity structure and conicity of inner-mold on shaping of hollow tubes were discussed.

探讨了浇注系统、浇注温度、牵引速度等工艺参数以及内结晶器的冷却腔结构和锥度等对空心管坯成形的影响规律。

2.It can be used in measuring not only dimensional and shape errors, but also relative positions as in the cases of perpendicularity, parallelness, conicity, distance between holes, etc.

它不仅能测量尺寸、形状误差，还可以测量垂直度、锥度、孔中心距、平行度等相互位置误差。

3.Tire structure unsymmetry results in conicity and ply-steering, and has significant influence on tire mechanical behavior.

轮胎因其结构不对称性导致的胎体锥度及帘布层转向效应，显著影响轮胎的力学特性。

4.It can be used in measuring not only dimensional and shape errors, but also relative positions as in the cases of perpendicularity, parallelness, conicity, distance between holes, etc.

它不仅能测量尺寸、形状误差，还可以测量垂直度、锥度、孔中心距、平行度等相互位置误差。

5.The engineer measured the conicity of the tire to ensure it met safety standards.

工程师测量了轮胎的锥度以确保其符合安全标准。

6.A higher conicity can lead to uneven wear on the tires.

更高的锥度可能导致轮胎不均匀磨损。

7.The design team focused on the conicity of the cone-shaped structure for optimal performance.

设计团队专注于锥形结构的锥度以实现最佳性能。

8.In aerodynamics, conicity affects the drag coefficient of the vehicle.

在空气动力学中，锥度影响车辆的阻力系数。

9.To improve stability, the conicity of the wheel should be within specified limits.

为了提高稳定性，轮子的锥度应在规定的范围内。

作文

In the realm of geometry and engineering, the term conicity refers to the degree of taper or cone-like shape that an object possesses. This concept is particularly important in various fields, including manufacturing, automotive design, and aerodynamics. Understanding conicity is essential for engineers and designers as it directly affects the performance and efficiency of products. For instance, when designing a car tire, the conicity of the tire can influence how well the vehicle handles on different surfaces and at various speeds.The significance of conicity extends beyond mere aesthetics; it plays a crucial role in functionality. A tire with an optimal conicity will provide better traction, stability, and control, ensuring a safer driving experience. Conversely, if the conicity is not properly calibrated, it can lead to uneven wear, reduced fuel efficiency, and compromised safety. Therefore, engineers must meticulously calculate the appropriate conicity during the design phase to meet safety standards and performance expectations.Moreover, conicity also has implications in the manufacturing process. For example, when producing components that require precise fitting, such as gears or bearings, the conicity must be carefully measured to ensure compatibility. If the conicity is off, it can result in mechanical failures or inefficiencies, leading to costly repairs and production delays. Thus, understanding the principles of conicity is vital for maintaining quality control in manufacturing.In addition to its technical applications, conicity can also be observed in nature. Many natural formations exhibit conical shapes, such as mountains, volcanoes, and even certain types of trees. These natural occurrences can inspire engineers and architects to incorporate conicity into their designs, creating structures that are not only functional but also aesthetically pleasing. For instance, the use of conicity in the design of skyscrapers can enhance wind resistance, allowing buildings to withstand harsh weather conditions.Furthermore, the concept of conicity is not limited to physical objects; it can also apply to abstract concepts such as data representation and statistical analysis. In data visualization, the conicity of a graph or chart can affect how information is perceived and interpreted. A well-designed graph that utilizes conicity effectively can make complex data more accessible and understandable to the audience.In conclusion, conicity is a multifaceted concept that permeates various disciplines, from engineering to art. Its importance cannot be overstated, as it impacts everything from product performance to aesthetic appeal. By grasping the principles of conicity, individuals in technical fields can enhance their designs and improve functionality, while those in creative professions can find inspiration in the natural world. Ultimately, a thorough understanding of conicity allows for the creation of innovative solutions that benefit society as a whole.

在几何和工程领域，术语conicity指的是物体所具有的锥形或渐缩形状的程度。这个概念在制造、汽车设计和空气动力学等多个领域中尤为重要。理解conicity对于工程师和设计师至关重要，因为它直接影响产品的性能和效率。例如，在设计汽车轮胎时，轮胎的conicity会影响车辆在不同表面和各种速度下的操控性能。conicity的重要性不仅仅体现在美学上；它在功能性方面也发挥着关键作用。具有最佳conicity的轮胎将提供更好的牵引力、稳定性和控制力，从而确保更安全的驾驶体验。相反，如果conicity未能正确校准，可能导致不均匀磨损、燃油效率降低和安全性受到影响。因此，工程师必须在设计阶段仔细计算适当的conicity以满足安全标准和性能预期。此外，conicity在制造过程中也有重要意义。例如，在生产需要精确配合的组件（如齿轮或轴承）时，必须仔细测量conicity以确保兼容性。如果conicity不准确，可能导致机械故障或效率低下，从而导致昂贵的维修和生产延误。因此，理解conicity的原理对于维持制造过程中的质量控制至关重要。除了技术应用，conicity还可以在自然界中观察到。许多自然形成物表现出锥形结构，例如山脉、火山甚至某些类型的树木。这些自然现象可以激励工程师和建筑师将conicity融入他们的设计中，创造出既功能性又美观的结构。例如，在摩天大楼的设计中使用conicity可以增强抗风能力，使建筑能够抵御恶劣的天气条件。此外，conicity的概念不仅限于物理对象；它还可以应用于数据表示和统计分析等抽象概念。在数据可视化中，图表的conicity会影响信息的感知和解读。一个设计良好的图表如果有效利用conicity，可以使复杂数据更易于被观众理解。总之，conicity是一个多方面的概念，渗透到各个学科，从工程到艺术。它的重要性不可小觑，因为它影响从产品性能到美学吸引力的一切。通过掌握conicity的原理，技术领域的个人可以提升他们的设计并改善功能，而创意职业的人则可以在自然界中找到灵感。最终，深入理解conicity可以创造出惠及整个社会的创新解决方案。