gravity base

简明释义

重力底座

英英释义

例句

1.The offshore platform relies on a robust gravity base 重力基础 to remain stable in turbulent waters.

该海上平台依靠坚固的gravity base 重力基础在波涛汹涌的水域中保持稳定。

2.Engineers must ensure that the gravity base 重力基础 of the structure can support its weight during extreme weather conditions.

工程师必须确保该结构的gravity base 重力基础能够在极端天气条件下支撑其重量。

3.The design team proposed a new gravity base 重力基础 system that would enhance the building's earthquake resistance.

设计团队提出了一种新的gravity base 重力基础系统，以增强建筑物的抗震能力。

4.The satellite was designed to operate efficiently from its gravity base 重力基础 on the lunar surface.

这颗卫星被设计为能够有效地从其位于月球表面的gravity base 重力基础上运行。

5.During the construction phase, workers focused on the integrity of the gravity base 重力基础 to prevent future collapses.

在施工阶段，工人们专注于gravity base 重力基础的完整性，以防止未来的倒塌。

作文

In the field of engineering and architecture, the concept of a gravity base plays a crucial role in ensuring stability and safety. A gravity base refers to a structure that relies on its weight to resist external forces, such as wind or seismic activity. This principle is particularly important in the design of buildings, bridges, and offshore platforms. By utilizing the natural force of gravity, engineers can create foundations that are both robust and efficient.One notable example of a gravity base is found in the construction of offshore wind farms. These wind turbines are often anchored to the seabed using large concrete bases that are heavy enough to withstand the forces of waves and currents. The design of these gravity bases ensures that the turbines remain upright and operational, even in harsh marine environments. The weight of the base keeps it securely in place, eliminating the need for additional anchoring systems that could complicate installation and maintenance.Moreover, the use of gravity bases is not limited to maritime structures. In urban settings, skyscrapers often employ a similar principle. The foundation of a tall building must counteract various forces, including those from the wind and the weight of the structure itself. Engineers calculate the necessary weight and dimensions of the gravity base to ensure that the building remains stable over time. This careful planning is essential for the safety of occupants and the longevity of the structure.The environmental impact of using gravity bases is also worth mentioning. By relying on weight rather than complex anchoring systems, these bases can reduce the amount of material needed for construction. This not only lowers costs but also minimizes the ecological footprint of the project. As sustainability becomes increasingly important in modern engineering practices, the adoption of gravity bases can contribute to more environmentally friendly designs.Additionally, the concept of a gravity base extends beyond traditional construction. In the realm of robotics and automation, certain machines utilize a gravity base to maintain stability during operation. For instance, robotic arms and automated guided vehicles (AGVs) often have weighted bases to prevent tipping and enhance performance. This application demonstrates the versatility of the gravity base concept across various industries.In conclusion, the gravity base is a fundamental aspect of engineering that underscores the importance of stability and safety in construction. Its applications range from offshore wind farms to towering skyscrapers, showcasing its adaptability and efficiency. As we continue to innovate and seek sustainable solutions, the principles behind the gravity base will undoubtedly remain relevant. Understanding this concept is essential for future engineers and architects who aspire to create safe, reliable, and environmentally conscious structures. The integration of gravity bases into modern design practices reflects a commitment to excellence in engineering, ensuring that our built environment can withstand the test of time.

在工程和建筑领域，重力基础的概念在确保稳定性和安全性方面发挥着至关重要的作用。重力基础是指依靠其重量抵抗外部力量（如风或地震活动）的结构。这个原理在建筑、桥梁和海上平台的设计中尤为重要。通过利用自然的重力，工程师可以创建既坚固又高效的基础。一个显著的例子是在海上风电场的建设中。风力涡轮机通常使用大型混凝土基础锚定在海床上，这些基础的重量足以抵御波浪和水流的力量。这些重力基础的设计确保涡轮机在恶劣的海洋环境中保持直立和正常运作。基础的重量使其稳固，就消除了需要额外锚固系统的复杂性，从而简化了安装和维护。此外，重力基础的使用并不限于海洋结构。在城市环境中，摩天大楼通常采用类似的原理。高楼的基础必须抵抗各种力量，包括来自风的力量和结构本身的重量。工程师计算所需的重量和重力基础的尺寸，以确保建筑在时间的推移中保持稳定。这种细致的规划对于居住者的安全和结构的耐久性至关重要。使用重力基础的环境影响也值得一提。通过依靠重量而不是复杂的锚固系统，这些基础可以减少建筑所需的材料量。这不仅降低了成本，还最小化了项目的生态足迹。随着可持续性在现代工程实践中变得越来越重要，采用重力基础能够推动更环保的设计。此外，重力基础的概念超出了传统建筑的范畴。在机器人和自动化领域，某些机器利用重力基础在操作过程中保持稳定。例如，机器人手臂和自动导引车（AGVs）通常具有加重的基础，以防止倾覆并增强性能。这一应用展示了重力基础概念在各个行业中的多样性。总之，重力基础是工程的一个基本方面，强调了在建筑中稳定性和安全性的重要性。它的应用范围从海上风电场到高耸的摩天大楼，展示了其适应性和效率。随着我们不断创新并寻求可持续解决方案，重力基础背后的原理无疑将继续保持相关性。理解这一概念对于未来的工程师和建筑师至关重要，他们渴望创造安全、可靠和环保的结构。将重力基础融入现代设计实践反映了对工程卓越的承诺，确保我们建造的环境能够经得住时间的考验。