anti-rolling effect

简明释义

减摇效果

英英释义

The anti-rolling effect refers to the mechanism or design feature that reduces or counteracts the tendency of a vehicle or object to roll over during movement or when subjected to lateral forces.

抗翻滚效果是指减少或抵消车辆或物体在运动或受到横向力时翻滚倾向的机制或设计特征。

例句

1.The bicycle features a low center of gravity for an improved anti-rolling effect 防倾覆效果 while riding.

这款自行车具有较低的重心,以提高骑行时的防倾覆效果

2.The architecture firm implemented an anti-rolling effect 防倾覆效果 in the building's design to withstand earthquakes.

建筑公司在建筑设计中实施了防倾覆效果以抵御地震。

3.The new suspension system in the car provides an excellent anti-rolling effect 防倾覆效果 during sharp turns.

汽车的新悬挂系统在急转弯时提供了出色的防倾覆效果

4.The foam padding in the backpack provides an anti-rolling effect 防倾覆效果 when placed on uneven surfaces.

背包中的泡沫衬垫在不平坦的表面上提供了防倾覆效果

5.To enhance stability, the yacht was designed with an anti-rolling effect 防倾覆效果 feature.

为了增强稳定性,这艘游艇设计了一个防倾覆效果功能。

作文

The concept of the anti-rolling effect plays a significant role in various fields, particularly in engineering and design. This phenomenon refers to the ability of a structure or vehicle to resist rolling over when subjected to lateral forces. Understanding this effect is crucial for ensuring safety and stability in vehicles, buildings, and other structures. In this essay, I will explore the importance of the anti-rolling effect, its applications, and how it contributes to the overall safety of different systems.To begin with, the anti-rolling effect is particularly vital in the automotive industry. Vehicles are designed with a low center of gravity to enhance stability. When a car takes a sharp turn, centrifugal force pushes it outward, creating a risk of rollover. The anti-rolling effect helps counteract this force by distributing weight and maintaining balance. Features such as wider wheelbases, advanced suspension systems, and electronic stability control all contribute to enhancing this effect. As a result, modern vehicles are not only more enjoyable to drive but also significantly safer.Moreover, the anti-rolling effect is essential in the construction of buildings and bridges. Engineers incorporate specific design elements, such as shear walls and cross-bracing, to increase the structure's resistance to lateral forces caused by wind or seismic activity. These features help ensure that buildings remain upright and stable, minimizing the risk of collapse during extreme weather events or earthquakes. Thus, the anti-rolling effect is a fundamental consideration in architectural design, contributing to the safety and longevity of structures.In addition to vehicles and buildings, the anti-rolling effect can also be observed in maritime applications. Ships and boats are designed with hull shapes that promote stability on the water. The distribution of weight and the shape of the hull work together to create an anti-rolling effect, allowing vessels to navigate through waves without capsizing. This is particularly important for large cargo ships and passenger vessels, where safety is paramount. Engineers continuously study and improve these designs to enhance the anti-rolling effect and ensure safe travel across oceans.Furthermore, the anti-rolling effect is not limited to physical structures; it also has implications in sports and recreational activities. For instance, in activities such as skateboarding or snowboarding, the center of gravity plays a crucial role in maintaining balance and preventing falls. Athletes learn to leverage their body weight to create an anti-rolling effect, allowing them to perform tricks and maneuvers with greater control. This understanding of balance and stability is essential for both safety and performance in these sports.In conclusion, the anti-rolling effect is a critical factor in ensuring stability and safety across various domains, including automotive design, architecture, maritime engineering, and even sports. By understanding and applying the principles behind this effect, engineers and designers can create safer vehicles, buildings, and recreational equipment. As technology continues to advance, further innovations will undoubtedly enhance the anti-rolling effect, leading to even greater safety standards in our daily lives. It is imperative that we continue to study and implement these principles to protect ourselves and our environments from potential hazards.

“抗翻滚效应”这一概念在多个领域中发挥着重要作用,尤其是在工程和设计方面。该现象指的是结构或车辆在受到横向力时抵抗翻倒的能力。理解这一效应对于确保车辆、建筑物和其他结构的安全性和稳定性至关重要。在这篇文章中,我将探讨“抗翻滚效应”的重要性、其应用以及它如何为不同系统的整体安全做出贡献。首先,“抗翻滚效应”在汽车工业中尤为重要。车辆被设计成低重心,以增强稳定性。当一辆车急转弯时,离心力会将其推向外侧,从而增加翻车的风险。“抗翻滚效应”通过分配重量和维持平衡来对抗这种力量。宽轮距、先进的悬挂系统和电子稳定控制等特征都在增强这一效应方面发挥了作用。因此,现代车辆不仅驾驶体验更佳,而且安全性显著提高。此外,“抗翻滚效应”在建筑和桥梁的建造中也至关重要。工程师们在设计中结合了特定的设计元素,如剪力墙和交叉支撑,以提高结构对风或地震等横向力量的抵抗力。这些特征有助于确保建筑在极端天气事件或地震期间保持直立和稳定,从而最大限度地减少倒塌的风险。因此,“抗翻滚效应”是建筑设计中的基本考虑因素,有助于结构的安全性和耐久性。除了车辆和建筑,“抗翻滚效应”还可以在海事应用中观察到。船舶和小艇的设计采用促进水上稳定性的船体形状。重量的分布与船体的形状共同作用,产生“抗翻滚效应”,使船只能够在波浪中航行而不翻覆。这对于大型货船和客船尤为重要,因为安全至关重要。工程师们不断研究和改进这些设计,以增强“抗翻滚效应”,确保安全的海洋旅行。此外,“抗翻滚效应”并不限于物理结构;它在体育和娱乐活动中也有影响。例如,在滑板或滑雪板等活动中,重心在保持平衡和防止摔倒方面起着至关重要的作用。运动员学习利用自己的体重来创造“抗翻滚效应”,使他们能够以更大的控制力进行特技和动作。这种对平衡和稳定性的理解对于这些运动的安全性和表现至关重要。总之,“抗翻滚效应”是确保各个领域(包括汽车设计、建筑、海洋工程甚至体育)稳定性和安全性的关键因素。通过理解和应用这一效应背后的原理,工程师和设计师可以创造出更安全的车辆、建筑和娱乐设备。随着技术的不断进步,进一步的创新无疑会增强“抗翻滚效应”,从而在我们的日常生活中达到更高的安全标准。继续研究和实施这些原则对于保护我们自己和我们的环境免受潜在危害至关重要。