ballast element

简明释义

1. 惰性元素; 2. 安定元素; 3. 镇定元素; 4. 稳定元素;

英英释义

例句

1.Adding a ballast element can help control the movement of the boat in rough waters.

添加一个压舱物元素可以帮助控制船只在恶劣水域中的运动。

2.The ship's stability was enhanced by adding a ballast element to the hull.

通过在船体中添加一个压舱物元素，船的稳定性得到了增强。

3.In construction, a ballast element is often used to provide weight and stability to structures.

在建筑中，压舱物元素常用于为结构提供重量和稳定性。

4.The model airplane required a ballast element to ensure it flew steadily during tests.

模型飞机需要一个压舱物元素以确保在测试期间飞行稳定。

5.The engineer designed a new ballast element to improve the aerodynamics of the vehicle.

工程师设计了一个新的压舱物元素以改善车辆的空气动力学性能。

作文

In the realm of engineering and construction, the concept of a ballast element plays a crucial role in ensuring stability and balance. A ballast element refers to any material or component that is used to provide weight and support to a structure, vehicle, or system. This term is often associated with ships, trains, and even buildings, where the distribution of weight is essential for safe and efficient operation. The primary function of a ballast element is to lower the center of gravity, which enhances the overall stability of the structure. For instance, in maritime engineering, ships are equipped with ballast elements such as water or heavy materials in their hulls to counteract the forces of wind and waves. Without these elements, a ship would be at risk of capsizing in rough waters.Similarly, in the context of rail transport, trains utilize ballast elements made from crushed stones placed beneath the tracks. This not only provides stability to the rails but also aids in drainage and reduces the growth of vegetation that could obstruct the tracks. The effectiveness of a train's operation heavily relies on the proper design and implementation of these ballast elements.Moreover, in architectural design, buildings often incorporate ballast elements in the form of concrete or masonry to ensure they can withstand various environmental forces. For example, skyscrapers are designed with specific ballast elements to resist high winds and seismic activity. Engineers meticulously calculate the weight and placement of these elements to maintain the structural integrity of the building.The significance of ballast elements extends beyond just physical stability; they also contribute to the overall efficiency of systems. In renewable energy applications, such as wind turbines, ballast elements are used to secure the base of the turbine against strong winds, ensuring that it remains operational under adverse conditions. This application illustrates how ballast elements are essential not only for stability but also for the functionality of modern technology.In conclusion, the role of a ballast element is multifaceted and indispensable across various fields of engineering. Whether in maritime, rail, or architectural contexts, these elements are vital for maintaining balance, stability, and safety. As technology continues to evolve, the design and application of ballast elements will likely become more sophisticated, further enhancing their importance in engineering practices. Understanding the principles behind ballast elements allows engineers and designers to create safer, more efficient structures and systems that can withstand the challenges presented by nature and use. Thus, the study of ballast elements is not just an academic exercise but a practical necessity in the quest for innovation and safety in engineering.

在工程和建筑领域，压舱物元素的概念在确保稳定和平衡方面发挥着至关重要的作用。压舱物元素是指用于为结构、车辆或系统提供重量和支持的任何材料或组件。这个术语通常与船舶、火车甚至建筑物相关联，因为重量的分布对于安全和高效的操作至关重要。压舱物元素的主要功能是降低重心，从而增强整体稳定性。例如，在海洋工程中，船舶的船体内装有水或重物等压舱物元素，以抵消风和波浪的力量。如果没有这些元素，船舶在恶劣水域中将面临倾覆的危险。同样，在铁路运输的背景下，火车利用放置在轨道下方的由碎石制成的压舱物元素。这不仅为轨道提供稳定性，还有助于排水，并减少可能阻碍轨道的植被生长。火车的有效运行在很大程度上依赖于这些压舱物元素的正确设计和实施。此外，在建筑设计中，建筑物通常将混凝土或砖石作为压舱物元素，以确保它们能够承受各种环境力量。例如，高楼大厦的设计中会加入特定的压舱物元素，以抵御强风和地震活动。工程师精确计算这些元素的重量和位置，以维持建筑的结构完整性。压舱物元素的重要性不仅限于物理稳定性；它们还对系统的整体效率做出了贡献。在可再生能源应用中，例如风力涡轮机，压舱物元素用于固定涡轮机基础，以抵御强风，确保其在恶劣条件下仍能正常运转。这一应用说明了压舱物元素不仅是稳定性的关键，也是现代技术功能的保障。总之，压舱物元素的作用是多方面的，在各个工程领域中不可或缺。无论是在海洋、铁路还是建筑环境中，这些元素对于保持平衡、稳定和安全至关重要。随着技术的不断发展，压舱物元素的设计和应用可能会变得更加复杂，进一步增强它们在工程实践中的重要性。理解压舱物元素背后的原理使工程师和设计师能够创造更安全、更高效的结构和系统，能够抵御自然和使用带来的挑战。因此，研究压舱物元素不仅是学术上的练习，而是在追求创新和工程安全过程中的实际必要性。