transverse fin

简明释义

横向肋片

英英释义

例句

1.The design of the aircraft incorporates a unique transverse fin to enhance stability during flight.

该飞机的设计采用了独特的横向鳍以增强飞行稳定性。

2.The transverse fin plays a crucial role in the maneuverability of certain marine vehicles.

对于某些海洋车辆来说，横向鳍在机动性方面起着至关重要的作用。

3.Engineers are experimenting with different shapes of transverse fin to improve the performance of drones.

工程师们正在尝试不同形状的横向鳍以提高无人机的性能。

4.The transverse fin on the top of the submarine helps to control its depth.

潜艇顶部的横向鳍有助于控制其深度。

5.In aquatic environments, fish often use their transverse fin for quick directional changes.

在水生环境中，鱼类常常利用它们的横向鳍进行快速的方向改变。

作文

In the realm of marine biology and aquatic engineering, the term transverse fin plays a crucial role in understanding the anatomy and functionality of various aquatic species and their designs. A transverse fin refers to a type of fin that is oriented perpendicular to the body of the fish or aquatic vehicle, providing stability and maneuverability in water. This unique orientation allows for improved lateral movement, which is essential for various activities such as swimming, turning, and maintaining balance in turbulent waters. One of the most fascinating aspects of the transverse fin is its evolutionary significance. Many fish species have developed this fin structure to adapt to their environments. For instance, the pectoral fins of certain fish, like the flying fish, are shaped in a transverse manner to help them glide above the water surface, escaping predators. The design of these fins not only aids in propulsion but also enhances the fish's ability to navigate through complex underwater terrains. Moreover, the concept of the transverse fin extends beyond biological organisms; it has been adopted in the field of engineering, particularly in the design of underwater vehicles and drones. Engineers have studied the mechanics of how these fins operate in natural systems to create more efficient and effective aquatic machines. For example, the incorporation of transverse fins in the design of submersibles can significantly improve their hydrodynamic efficiency, allowing them to move swiftly and quietly through the water. The study of transverse fins also opens up discussions about biomimicry, where human innovations are inspired by nature. By examining how fish utilize their fins for optimal performance, scientists and engineers can replicate these features in their designs. This approach not only enhances the functionality of aquatic vehicles but also promotes sustainability, as designs inspired by nature often require less energy and resources. Furthermore, the importance of transverse fins is evident in recreational activities such as surfing and diving. Understanding the dynamics of water flow around different fin shapes can help surfers choose the right board for their style and skill level. Similarly, divers can benefit from knowledge about how fins work to improve their swimming techniques and conserve energy while exploring underwater environments. In conclusion, the transverse fin serves as a remarkable example of how nature’s designs can influence both biological evolution and technological advancements. Its significance spans across various fields, from marine biology to engineering and recreation. As we continue to explore the intricacies of aquatic life and the principles governing fluid dynamics, the study of transverse fins will undoubtedly remain a vital area of interest, inspiring future innovations and fostering a deeper appreciation for the wonders of the natural world.

在海洋生物学和水下工程领域，术语横向鳍在理解各种水生物种及其设计的解剖学和功能性方面起着至关重要的作用。横向鳍指的是一种与鱼体或水下载体的主体呈垂直方向的鳍，提供了在水中的稳定性和机动性。这种独特的方向使得改善横向运动成为可能，这对游泳、转弯和在湍急水域中保持平衡等各种活动至关重要。横向鳍最迷人的方面之一是其进化意义。许多鱼类已经发展出这种鳍结构，以适应它们的环境。例如，某些鱼类（如飞鱼）的胸鳍呈横向形状，以帮助它们在水面上滑翔，逃避捕食者。这些鳍的设计不仅有助于推进，还增强了鱼类在复杂水下地形中导航的能力。此外，横向鳍的概念超越了生物有机体；它已被应用于工程领域，特别是在水下车辆和无人机的设计中。工程师们研究了这些鳍在自然系统中如何运作的机制，以创造更高效、更有效的水下机器。例如，在潜水器的设计中融入横向鳍可以显著提高其流体动力效率，使它们能够迅速而安静地穿行于水中。横向鳍的研究还引发了关于仿生学的讨论，人类的创新受到自然的启发。通过研究鱼类如何利用其鳍实现最佳性能，科学家和工程师可以在他们的设计中复制这些特征。这种方法不仅增强了水下车辆的功能性，而且促进了可持续性，因为受自然启发的设计往往需要更少的能源和资源。此外，横向鳍的重要性在冲浪和潜水等休闲活动中也显而易见。了解不同鳍形状周围水流的动态可以帮助冲浪者选择适合他们风格和技能水平的板子。同样，潜水员可以利用对鳍工作原理的知识来改善他们的游泳技巧，并在探索水下环境时节省能量。总之，横向鳍作为自然设计如何影响生物进化和技术进步的杰出例子。它的重要性跨越多个领域，从海洋生物学到工程和休闲。随着我们继续探索水生生命的复杂性和流体动力学的原则，横向鳍的研究无疑将成为一个重要的兴趣领域，激励未来的创新，并加深我们对自然世界奇观的欣赏。