synchronous heaving

简明释义

谐振垂荡

英英释义

例句

1.During the test, the platform exhibited synchronous heaving when subjected to wave simulations.

在测试过程中，该平台在受到波浪模拟时表现出同步起伏。

2.Engineers designed the bridge to withstand synchronous heaving caused by seismic activity.

工程师们设计了这座桥，以抵御由地震活动引起的同步起伏。

3.The ship experienced synchronous heaving during the storm, causing it to rise and fall in a coordinated manner with the waves.

船在风暴中经历了同步起伏，导致它与波浪协调地上下起伏。

4.The research focused on the effects of synchronous heaving on marine structures.

研究集中在同步起伏对海洋结构的影响上。

5.In underwater robotics, synchronous heaving can affect the stability of the vehicle.

在水下机器人技术中，同步起伏可能会影响车辆的稳定性。

作文

In the realm of engineering and physics, the term synchronous heaving refers to a coordinated upward and downward movement that occurs simultaneously across different points of a structure or system. This phenomenon can be observed in various scenarios, from the oscillations of a bridge under load to the behavior of ocean waves affecting multiple ships at once. Understanding synchronous heaving is crucial for engineers and designers as it can significantly influence the safety and functionality of structures. For instance, when designing bridges, engineers must consider how the bridge will react to the weight of vehicles moving across it. If multiple vehicles are on the bridge at the same time, their combined weight can lead to a situation where synchronous heaving occurs. This means that certain sections of the bridge may experience upward movements while others may move downward, creating stress points that could compromise the integrity of the structure. Therefore, incorporating the principles of synchronous heaving into the design process helps in creating safer and more resilient infrastructures.Moreover, synchronous heaving is not limited to static structures but also plays a significant role in dynamic systems such as aircraft and ships. In aviation, the concept is vital during turbulence; when an aircraft encounters uneven air currents, different parts of the plane may experience varying degrees of lift and drag, leading to a synchronous heaving effect. Pilots must be trained to handle these situations effectively to maintain control and ensure passenger safety.In maritime contexts, synchronous heaving can be observed when several vessels are affected by the same wave patterns. For example, during a storm, multiple ships may rise and fall in unison, which can lead to dangerous conditions if they are too close to each other. Understanding this behavior allows naval architects to design ships that can better withstand such forces, ensuring the safety of both the vessels and their crews.The study of synchronous heaving also extends into the field of robotics, where engineers develop robots that mimic human or animal movements. In these designs, achieving synchronous heaving among robotic limbs is essential for fluid motion and effective task performance. This application not only enhances the functionality of robots but also contributes to advancements in fields such as prosthetics, where synchronized movements can lead to more natural and effective use of artificial limbs.In conclusion, the concept of synchronous heaving is integral to various fields, including civil engineering, aviation, maritime studies, and robotics. Its implications are vast, influencing the design and operation of many systems we rely on daily. By understanding and applying the principles of synchronous heaving, professionals can create safer, more efficient, and innovative solutions to complex challenges. The importance of this concept cannot be overstated, as it continues to play a pivotal role in technological advancements and the development of robust infrastructures that withstand the test of time.

在工程和物理学领域，术语synchronous heaving指的是在结构或系统的不同点之间同时发生的协调向上和向下的运动。这种现象可以在各种场景中观察到，从桥梁在负载下的振动到海浪影响多个船只的行为。理解synchronous heaving对工程师和设计师至关重要，因为它会显著影响结构的安全性和功能性。例如，在设计桥梁时，工程师必须考虑桥梁在车辆通过时的反应。如果多辆车辆同时在桥上，它们的总重可能导致synchronous heaving的情况发生。这意味着桥梁的某些部分可能会向上移动，而其他部分则可能向下移动，从而产生压力点，可能会影响该结构的完整性。因此，将synchronous heaving的原理纳入设计过程中，有助于创建更安全、更具韧性的基础设施。此外，synchronous heaving不仅限于静态结构，还在动态系统中发挥着重要作用，例如飞机和船只。在航空领域，该概念在遇到颠簸时至关重要；当飞机遭遇不均匀的气流时，飞机的不同部分可能会经历不同程度的升力和阻力，从而导致synchronous heaving效应。飞行员必须接受培训，以有效处理这些情况，以保持控制并确保乘客安全。在海事环境中，synchronous heaving可以在多个船只受到相同波浪模式影响时观察到。例如，在暴风雨期间，多个船只可能会同步上下起伏，如果它们太靠近彼此，可能会导致危险的情况。理解这种行为使得海洋建筑师能够设计出更能承受这种力量的船只，确保船只及其船员的安全。synchronous heaving的研究还扩展到机器人领域，工程师开发出模仿人类或动物运动的机器人。在这些设计中，实现机器人肢体之间的synchronous heaving对于流畅的运动和有效的任务执行至关重要。这一应用不仅增强了机器人的功能性，还促进了义肢等领域的进步，在这些领域中，协调的运动可以导致更自然和有效的人工肢体使用。总之，synchronous heaving的概念在土木工程、航空、海事研究和机器人等多个领域中都是不可或缺的。它的影响是广泛的，影响着我们日常依赖的许多系统的设计和操作。通过理解和应用synchronous heaving的原理，专业人士可以创造出更安全、更高效和创新的解决方案来应对复杂的挑战。这个概念的重要性不容小觑，因为它继续在技术进步和开发经得起时间考验的坚固基础设施方面发挥着关键作用。