heaving oscillation

简明释义

垂荡

英英释义

例句

1.During the test, the platform exhibited heaving oscillation, which was unexpected.

在测试过程中，平台表现出起伏振荡，这是意料之外的。

2.The buoy's sensors detected heaving oscillation in the water, indicating rough sea conditions.

浮标的传感器检测到水中的起伏振荡，这表明海况恶劣。

3.The heaving oscillation of the ground made it difficult for the construction team to work safely.

地面的起伏振荡使得施工团队难以安全作业。

4.Engineers need to account for heaving oscillation when designing structures in earthquake-prone areas.

在设计地震多发地区的结构时，工程师需要考虑起伏振荡。

5.The ship experienced a severe heaving oscillation during the storm, causing discomfort to the passengers.

在暴风雨中，船只经历了严重的起伏振荡，导致乘客感到不适。

作文

In the realm of physics and engineering, understanding various types of movements is crucial for designing systems that interact with forces and materials. One such movement that often comes up in discussions about dynamic systems is heaving oscillation. This term refers to a specific type of oscillatory motion characterized by vertical movement, usually in the context of waves or vibrations. When we talk about heaving oscillation (起伏振荡), we are often referring to how objects move up and down in response to external forces, such as water waves acting on a ship or vibrations caused by machinery. To illustrate this concept, let’s consider a ship navigating through turbulent waters. As the vessel encounters waves, it experiences a series of heaving oscillations (起伏振荡) as it rises and falls with the swell of the sea. This motion is not only important for the comfort of passengers but also for the integrity of the ship itself. Engineers must account for these oscillations when designing ships, ensuring that they can withstand the forces at play without suffering structural damage. Moreover, heaving oscillation (起伏振荡) is not limited to maritime contexts. In civil engineering, it plays a significant role when considering the impact of seismic activity on buildings. During an earthquake, structures may experience heaving oscillations (起伏振荡) as the ground shifts beneath them. Understanding how these oscillations affect a building's stability is vital for architects and engineers, who strive to create safe and resilient structures. In addition to practical applications, heaving oscillation (起伏振荡) is also a fascinating subject of study in physics. Researchers delve into the underlying principles of oscillatory motion, exploring how factors like frequency, amplitude, and damping influence the behavior of oscillating systems. For instance, a pendulum exhibits heaving oscillation (起伏振荡) as it swings back and forth; however, if the pendulum were to experience resistance, its oscillations would gradually diminish, demonstrating the concept of damping in action. Furthermore, heaving oscillation (起伏振荡) can be observed in various natural phenomena, such as ocean waves, sound waves, and even in the vibration of musical instruments. Each of these examples showcases the fundamental nature of oscillation and its relevance across different fields of study. By examining these movements, scientists and engineers can gain insights into the behavior of complex systems, leading to innovations and improvements in technology. In conclusion, the concept of heaving oscillation (起伏振荡) is integral to our understanding of both natural and engineered systems. Whether it's a ship bobbing on the waves, a building swaying during an earthquake, or a pendulum swinging in a quiet room, the principles of oscillation govern much of the physical world around us. As we continue to explore and study these movements, we unlock new possibilities for design, safety, and efficiency in various applications. The intricate dance of heaving oscillation (起伏振荡) remains a captivating topic that bridges the gap between theory and practical application, highlighting the beauty of physics in our everyday lives.

在物理和工程学领域，理解各种运动类型对于设计与力和材料相互作用的系统至关重要。其中一个常提到的运动是heaving oscillation。这个术语指的是一种特定的振荡运动，其特点是垂直运动，通常与波动或振动有关。当我们谈论heaving oscillation（起伏振荡）时，通常是指物体如何在外部力的作用下上下移动，例如水波对船只的作用或机械引起的振动。为了说明这一概念，让我们考虑一艘船在波涛汹涌的水域航行。当船只遇到波浪时，它会经历一系列的heaving oscillations（起伏振荡），随着海浪的起伏而上下浮动。这种运动不仅对乘客的舒适性重要，而且对船只本身的完整性也至关重要。工程师在设计船只时必须考虑这些振荡，确保它们能够承受作用力而不遭受结构损坏。此外，heaving oscillation（起伏振荡）并不局限于海洋环境。在土木工程中，当考虑地震活动对建筑物的影响时，它发挥着重要作用。在地震期间，结构可能会经历heaving oscillations（起伏振荡），因为地面在其下面移动。理解这些振荡如何影响建筑物的稳定性对建筑师和工程师至关重要，他们努力创造安全和韧性的结构。除了实际应用之外，heaving oscillation（起伏振荡）也是物理学研究中的一个迷人课题。研究人员深入探讨振荡运动的基本原理，探索频率、振幅和阻尼等因素如何影响振荡系统的行为。例如，摆锤在来回摆动时表现出heaving oscillation（起伏振荡）；然而，如果摆锤受到阻力，它的振荡将逐渐减弱，展示了阻尼的概念。此外，heaving oscillation（起伏振荡）可以在各种自然现象中观察到，例如海洋波浪、声波，甚至是乐器的振动。这些例子展示了振荡的基本性质及其在不同研究领域的相关性。通过研究这些运动，科学家和工程师可以获得关于复杂系统行为的见解，从而推动技术的创新和改进。总之，heaving oscillation（起伏振荡）的概念是我们理解自然和工程系统的基础。无论是船只在波浪上摇摆、建筑物在地震中摇晃，还是安静房间里摆锤的摆动，振荡的原理支配着我们周围的物理世界。随着我们继续探索和研究这些运动，我们为各种应用的设计、安全和效率开辟了新的可能性。heaving oscillation（起伏振荡）的复杂舞蹈仍然是一个引人入胜的话题，架起了理论与实践应用之间的桥梁，突显了物理学在我们日常生活中的美丽。