immersed wedge

简明释义

浸水楔形

英英释义

例句

1.To calculate the pressure distribution, we need to analyze the immersed wedge in various fluid conditions.

为了计算压力分布，我们需要分析在各种流体条件下的浸没楔形体。

2.During the experiment, we observed how the immersed wedge affected the flow of water around it.

在实验中，我们观察到浸没楔形体如何影响周围水流。

3.The engineer designed an immersed wedge to improve the stability of the underwater structure.

工程师设计了一个浸没楔形体以提高水下结构的稳定性。

4.The immersed wedge can be used to create a barrier against strong currents in rivers.

可以使用浸没楔形体在河流中创建对抗强水流的屏障。

5.The immersed wedge design was crucial for the success of the underwater construction project.

该浸没楔形体设计对于水下建设项目的成功至关重要。

作文

In the realm of physics and engineering, the concept of an immersed wedge plays a pivotal role in understanding how forces interact with objects submerged in fluids. An immersed wedge can be defined as a wedge-shaped object that is partially or fully submerged in a fluid, such as water or air. This phenomenon is particularly significant when analyzing buoyancy, pressure distribution, and the stability of floating or submerged bodies. The study of immersed wedges provides valuable insights into various applications, ranging from naval architecture to civil engineering.To illustrate the importance of an immersed wedge, let us consider a practical example involving a boat. When a boat is placed in water, it displaces a certain volume of water equal to its weight. The shape of the hull can be likened to an immersed wedge, which allows the boat to float while maintaining stability. The angle of the wedge affects the distribution of pressure along the submerged surface, influencing how the boat interacts with the water around it.Furthermore, the principles governing an immersed wedge extend beyond just boats. In construction, engineers often design structures that must withstand fluid pressures, such as dams or underwater tunnels. Understanding how an immersed wedge behaves under different conditions helps engineers create safer and more efficient designs. For instance, when calculating the forces acting on a dam, engineers must take into account the pressure exerted by the water on the immersed wedge shape of the dam's base.Another fascinating aspect of immersed wedges lies in their application in hydraulic systems. Many machines rely on the principles of hydraulics to function effectively. By utilizing the concept of an immersed wedge, engineers can design hydraulic lifts, presses, and other equipment that rely on the pressure exerted by fluids. The ability to manipulate the shape and orientation of an immersed wedge allows for precise control over force and motion in these systems.Moreover, the study of immersed wedges is not limited to static scenarios. Dynamic interactions, such as those experienced by submarines or underwater vehicles, also highlight the significance of this concept. As these vehicles navigate through water, their shapes can be analyzed as immersed wedges, helping engineers optimize their designs for better hydrodynamics and fuel efficiency.In conclusion, the concept of an immersed wedge is fundamental in various fields, including physics, engineering, and environmental science. Whether it is analyzing the stability of a boat, designing a dam, or optimizing hydraulic systems, understanding the behavior of immersed wedges is crucial for achieving desired outcomes. As we continue to explore the intricacies of fluid dynamics and solid mechanics, the importance of immersed wedges will undoubtedly remain a key topic of study and application in the future.

在物理和工程领域，‘浸入楔形体’的概念在理解流体中物体之间的力如何相互作用方面发挥着关键作用。‘浸入楔形体’可以定义为部分或完全浸没在流体（如水或空气）中的楔形物体。这一现象在分析浮力、压力分布以及漂浮或浸没物体的稳定性时尤其重要。对‘浸入楔形体’的研究为从海军建筑到土木工程的各种应用提供了宝贵的见解。为了说明‘浸入楔形体’的重要性，让我们考虑一个涉及船只的实际例子。当一艘船被放置在水中时，它会排开与其重量相等的水量。船体的形状可以比作一个‘浸入楔形体’，它使船能够浮起并保持稳定。楔形的角度影响着沿着浸没表面的压力分布，从而影响船只与周围水的相互作用。此外， governing ‘浸入楔形体’的原理不仅限于船只。在建筑中，工程师通常设计必须承受流体压力的结构，例如大坝或水下隧道。理解‘浸入楔形体’在不同条件下的行为有助于工程师创建更安全、更高效的设计。例如，在计算大坝上作用的力时，工程师必须考虑水对大坝基础的‘浸入楔形体’形状施加的压力。‘浸入楔形体’的另一个迷人之处在于它在液压系统中的应用。许多机器依赖液压原理有效运作。通过利用‘浸入楔形体’的概念，工程师可以设计液压升降机、压机和其他依赖流体施加的压力的设备。操控‘浸入楔形体’的形状和方向使得这些系统中的力和运动能够得到精确控制。此外，‘浸入楔形体’的研究不仅限于静态场景。动态交互，例如潜艇或水下车辆所经历的情况，也突显了这一概念的重要性。当这些车辆在水中航行时，它们的形状可以被分析为‘浸入楔形体’，帮助工程师优化其设计以获得更好的流体动力学和燃油效率。总之，‘浸入楔形体’的概念在物理、工程和环境科学等多个领域都是基础性的。无论是分析船只的稳定性、设计大坝还是优化液压系统，理解‘浸入楔形体’的行为对于实现期望结果至关重要。随着我们继续探索流体动力学和固体力学的复杂性，‘浸入楔形体’的重要性无疑将仍然是未来研究和应用的关键主题。