capsizing moment engine
简明释义
绞盘机
英英释义
例句
1.During the simulation, the capsizing moment engine showed how quickly a boat could tip over.
在模拟过程中,翻覆时刻引擎展示了船只翻转的快速程度。
2.Understanding the capsizing moment engine is crucial for naval architects.
理解翻覆时刻引擎对海军建筑师至关重要。
3.Engineers are testing the capsizing moment engine to improve the safety of large vessels.
工程师正在测试翻覆时刻引擎以提高大型船舶的安全性。
4.The capsizing moment engine plays a vital role in the stability of sailing boats.
在帆船的稳定性中,翻覆时刻引擎起着至关重要的作用。
5.The new boat design incorporates a more stable capsizing moment engine to prevent accidents.
新的船只设计采用了更稳定的翻覆时刻引擎以防止事故。
作文
In the world of engineering and design, the concept of a capsizing moment engine is crucial for understanding stability and balance in various structures and vehicles. The term refers to the point at which an object, such as a ship or a vehicle, becomes unstable and is at risk of tipping over due to external forces or internal weight distribution. Understanding this phenomenon is vital for engineers who aim to create safe and efficient designs. This essay will explore the significance of the capsizing moment engine and its implications in real-world applications.The capsizing moment engine is not just a theoretical construct; it has practical applications in marine engineering, automotive design, and even in architecture. For instance, in naval architecture, the stability of a vessel is often assessed by calculating its center of gravity and the metacentric height. When a ship encounters rough seas, the forces acting upon it can create a moment that may lead to capsizing. Engineers must ensure that the design of the ship minimizes this risk by carefully considering the distribution of weight and the shape of the hull.Similarly, in the automotive industry, the capsizing moment engine plays a significant role in vehicle stability. Sports cars, for example, are designed with a low center of gravity to enhance their handling and reduce the likelihood of rollover during sharp turns. The placement of heavy components, such as the engine and battery, is strategically done to maintain balance and prevent unwanted moments that could lead to capsizing.Furthermore, the concept of the capsizing moment engine extends beyond vehicles and vessels. In architecture, buildings must be designed to withstand lateral forces, such as those caused by wind or earthquakes. Engineers use principles related to the capsizing moment to ensure that structures remain upright and stable under various conditions. This involves calculating moments and forces that could potentially lead to structural failure.In conclusion, the capsizing moment engine is a fundamental principle in engineering that addresses the stability of objects subjected to external forces. Whether in marine design, automotive engineering, or architecture, understanding how to manage and mitigate the risks associated with capsizing moments is essential for creating safe and effective designs. As technology advances, the application of this principle will continue to evolve, leading to innovations that enhance safety and performance in various fields. Engineers must remain vigilant and informed about the dynamics of stability to ensure that their designs can withstand the challenges posed by the environment and operational conditions. Ultimately, the mastery of the capsizing moment engine will contribute to safer and more reliable structures and vehicles, benefiting society as a whole.
在工程和设计的世界中,翻船时刻引擎的概念对于理解各种结构和车辆的稳定性和平衡至关重要。该术语指的是一个物体(例如船只或车辆)在外力或内部重量分布的影响下变得不稳定并有倾覆风险的时刻。理解这一现象对工程师来说至关重要,他们旨在创造安全高效的设计。本文将探讨翻船时刻引擎的重要性及其在现实应用中的影响。翻船时刻引擎不仅是一个理论构想;它在海洋工程、汽车设计甚至建筑领域都有实际应用。例如,在船舶设计中,通常通过计算重心和元心高度来评估船只的稳定性。当船只遇到波涛汹涌的海面时,作用于其上的力量可能会产生一个时刻,从而导致翻船。工程师必须确保船只的设计尽量减少这种风险,仔细考虑重量分布和船体形状。同样,在汽车工业中,翻船时刻引擎在车辆稳定性方面发挥着重要作用。例如,跑车通常设计为低重心,以增强操控性并减少在急转弯时翻车的可能性。重型组件(如发动机和电池)的放置经过精心设计,以保持平衡,防止可能导致翻船的不必要时刻。此外,翻船时刻引擎的概念超越了车辆和船只。在建筑中,建筑物必须设计成能够承受侧向力量,例如风或地震造成的力量。工程师使用与翻船时刻相关的原理,确保结构在各种条件下保持直立和稳定。这涉及计算可能导致结构失效的时刻和力量。总之,翻船时刻引擎是工程中的一个基本原理,解决了受到外力作用的物体的稳定性问题。无论是在海洋设计、汽车工程还是建筑学中,理解如何管理和减轻与翻船时刻相关的风险,对于创建安全有效的设计至关重要。随着技术的进步,这一原理的应用将继续发展,推动各个领域的创新,提高安全性和性能。工程师必须保持警觉,了解稳定性的动态,以确保他们的设计能够抵御环境和操作条件带来的挑战。最终,掌握翻船时刻引擎将有助于创造更安全、更可靠的结构和车辆,使整个社会受益。
