bearing area

简明释义

支承面积

英英释义

例句

1.The foundation's bearing area needs to be reinforced for heavy machinery.

基础的承载区域需要加固以支持重型机械。

2.The design of the bridge must consider the load distribution on the bearing area.

桥梁的设计必须考虑到承载区域的负载分布。

3.Engineers calculated the bearing area to ensure the structure's stability.

工程师计算了承载区域以确保结构的稳定性。

4.In construction, a larger bearing area can help distribute weight more evenly.

在建筑中，较大的承载区域可以帮助更均匀地分配重量。

5.A proper assessment of the bearing area is crucial for safety.

对承载区域的适当评估对安全至关重要。

作文

The concept of the bearing area is crucial in various fields, particularly in engineering and architecture. It refers to the surface area that supports a load or weight, ensuring stability and safety in structures. Understanding the bearing area is essential for designing buildings, bridges, and other infrastructure. For instance, when engineers calculate the bearing area of a foundation, they must consider the weight of the structure and the type of soil it rests upon. A larger bearing area can help distribute the weight more evenly, reducing the risk of settlement or failure. In practical terms, the bearing area can be influenced by several factors, including material properties, load conditions, and environmental factors. For example, a concrete slab's bearing area will differ from that of a wooden beam due to their distinct material characteristics. Engineers often use formulas to determine the optimal bearing area necessary to support specific loads, which is vital in preventing structural damage over time. Moreover, the bearing area plays a significant role in geotechnical engineering. When assessing soil stability, engineers evaluate the bearing area to ensure that the ground can adequately support the loads imposed by structures above. If the bearing area is insufficient, it may lead to excessive settlement or even catastrophic failure of the structure. This is why soil tests are often conducted to determine its load-bearing capacity, which directly influences the design of foundations. In addition to its importance in structural integrity, the bearing area also has implications for safety regulations. Building codes typically stipulate minimum requirements for the bearing area to ensure that structures can withstand expected loads and environmental conditions. Compliance with these codes is not only a legal obligation but also a moral one, as it protects the lives of those who occupy or use the structures. Furthermore, the concept of bearing area extends beyond traditional construction. In renewable energy projects, such as wind turbines, the bearing area of the base must be sufficiently large to withstand the forces generated by wind and the weight of the turbine itself. Similarly, in transportation infrastructure, the bearing area of roads and bridges must be designed to accommodate heavy vehicle loads while ensuring long-term durability. In conclusion, the bearing area is a fundamental aspect of engineering that impacts the safety, stability, and longevity of structures. By carefully calculating and optimizing the bearing area, engineers can create resilient designs that meet both functional and safety requirements. As we continue to innovate in construction and design, understanding the principles behind the bearing area will remain essential for future developments in the field.

“承载面积”这一概念在各个领域中都至关重要，特别是在工程和建筑学中。它指的是支持负载或重量的表面区域，确保结构的稳定性和安全性。理解“承载面积”对于设计建筑物、桥梁和其他基础设施至关重要。例如，当工程师计算基础的“承载面积”时，他们必须考虑结构的重量以及其所依赖的土壤类型。更大的“承载面积”可以帮助更均匀地分配重量，从而减少沉降或失效的风险。在实际操作中，“承载面积”受多种因素的影响，包括材料特性、负载条件和环境因素。例如，混凝土板的“承载面积”与木梁的“承载面积”会有所不同，因为它们具有不同的材料特征。工程师通常使用公式来确定支撑特定负载所需的最佳“承载面积”，这对于防止结构随时间发生损坏至关重要。此外，“承载面积”在岩土工程中也发挥着重要作用。在评估土壤稳定性时，工程师会评估“承载面积”，以确保地面能够充分支撑上方施加的负载。如果“承载面积”不足，可能会导致过度沉降甚至结构的灾难性失效。这就是为什么通常会进行土壤测试，以确定其承载能力，这直接影响基础的设计。除了在结构完整性方面的重要性外，“承载面积”还对安全法规产生影响。建筑规范通常规定了“承载面积”的最低要求，以确保结构能够承受预期的负载和环境条件。遵守这些规范不仅是法律义务，也是道德义务，因为它保护了占用或使用这些结构的人的生命。此外，“承载面积”的概念超越了传统建筑。在可再生能源项目中，例如风力涡轮机，其基础的“承载面积”必须足够大，以承受风产生的力量和涡轮机本身的重量。类似地，在交通基础设施中，道路和桥梁的“承载面积”必须设计成能够容纳重型车辆负载，同时确保长期耐久性。总之，“承载面积”是工程学的一个基本方面，它影响结构的安全性、稳定性和耐久性。通过仔细计算和优化“承载面积”，工程师可以创建满足功能和安全要求的坚固设计。随着我们在建筑和设计领域的不断创新，理解“承载面积”背后的原理将继续对未来的发展至关重要。