external cone angle

简明释义

面角

英英释义

例句

1.In manufacturing, adjusting the external cone angle 外部锥角 can significantly affect the product's aerodynamics.

在制造过程中，调整外部锥角 external cone angle可以显著影响产品的气动性能。

2.Engineers must calculate the external cone angle 外部锥角 when designing a new exhaust system.

工程师在设计新的排气系统时必须计算外部锥角 external cone angle。

3.The external cone angle 外部锥角 of the nozzle determines how the fluid expands after exiting.

喷嘴的外部锥角 external cone angle决定了流体在排出后如何扩展。

4.The design of the funnel requires careful consideration of the external cone angle 外部锥角 to ensure optimal flow.

漏斗的设计需要仔细考虑外部锥角 external cone angle，以确保最佳流动。

5.A larger external cone angle 外部锥角 can improve mixing efficiency in certain applications.

在某些应用中，较大的外部锥角 external cone angle可以提高混合效率。

作文

Understanding the concept of external cone angle is crucial in various fields, particularly in engineering and design. The term refers to the angle formed between the axis of a cone and a line drawn from the apex to the edge of the base. This angle plays a significant role in determining the shape and structure of conical objects, which are prevalent in both natural formations and human-made structures. For instance, in architecture, the external cone angle influences how a roof directs water runoff, impacting its durability and functionality. Similarly, in mechanical engineering, the angle can affect the flow of materials in hoppers and silos, ensuring efficient processing and minimizing waste.In the context of fluid dynamics, the external cone angle is vital when analyzing the behavior of fluids as they interact with conical surfaces. The angle can affect the velocity and pressure distribution around the cone, which is essential for designing efficient systems in industries such as aerospace and automotive. Engineers often use computational fluid dynamics (CFD) simulations to visualize how changes in the external cone angle can lead to different performance outcomes. By adjusting this angle, engineers can optimize designs for better aerodynamics or hydrodynamics, ultimately leading to improved efficiency and reduced energy consumption.Moreover, the external cone angle also has implications in the field of optics. In lens design, for example, the angle can determine how light is refracted as it passes through conical shapes, affecting the quality of images produced. Understanding the relationship between the external cone angle and light behavior is essential for creating high-performance optical devices such as cameras, microscopes, and telescopes.Additionally, the external cone angle is relevant in geology, where it can describe the shape of volcanic cones. The angle of the cone can indicate the type of eruption and the materials ejected during volcanic activity. A steeper angle may suggest explosive eruptions, while a gentler slope might indicate effusive eruptions. Geologists study these angles to predict future volcanic behavior and assess potential hazards to nearby communities.In summary, the external cone angle is a multifaceted concept that transcends various disciplines, from engineering and fluid dynamics to optics and geology. Its significance lies in its ability to influence the performance and efficiency of systems and structures. By mastering the understanding of the external cone angle, professionals in these fields can enhance their designs, improve safety, and contribute to technological advancements. As we continue to explore and innovate, the importance of such geometric principles will remain at the forefront of scientific and engineering endeavors.

理解外锥角这一概念在多个领域中至关重要，特别是在工程和设计中。这个术语指的是锥体的轴线与从顶点到基底边缘绘制的线之间形成的角度。这个角度在决定锥形物体的形状和结构方面起着重要作用，这些物体在自然形成和人造结构中都很常见。例如，在建筑学中，外锥角影响屋顶如何引导雨水流动，从而影响其耐用性和功能性。同样，在机械工程中，这个角度可以影响料斗和筒仓中材料的流动，确保高效处理并最小化浪费。在流体动力学的背景下，外锥角在分析流体与锥形表面相互作用时至关重要。这个角度可以影响锥体周围的速度和压力分布，这对于航空航天和汽车等行业的高效系统设计至关重要。工程师们经常使用计算流体动力学（CFD）模拟来可视化对外锥角的变化如何导致不同的性能结果。通过调整这个角度，工程师可以优化设计以提高空气动力学或水动力学，最终实现更高的效率和减少能源消耗。此外，外锥角在光学领域也很重要。在镜头设计中，例如，这个角度可以决定光线通过锥形物体时的折射方式，从而影响所产生图像的质量。理解外锥角与光行为之间的关系对于创造高性能光学设备（如相机、显微镜和望远镜）至关重要。此外，外锥角在地质学中也相关，它可以描述火山锥的形状。锥体的角度可以指示喷发的类型以及喷发过程中排出的材料。更陡的角度可能表明爆炸性喷发，而较缓的坡度可能表示流出性喷发。地质学家研究这些角度以预测未来的火山行为并评估对附近社区的潜在危害。总之，外锥角是一个多方面的概念，超越了多个学科，从工程和流体动力学到光学和地质学。其重要性在于它能够影响系统和结构的性能和效率。通过掌握对外锥角的理解，这些领域的专业人士可以提升他们的设计、改善安全，并为技术进步做出贡献。随着我们继续探索和创新，这种几何原理的重要性将始终处于科学和工程工作的前沿。