arch stability

简明释义

砂拱稳定性;

英英释义

例句

1.The design of the bridge ensures adequate arch stability 拱形稳定性 to withstand heavy traffic.

这座桥的设计确保了足够的拱形稳定性 arch stability以承受繁重的交通。

2.In architectural terms, arch stability 拱形稳定性 is crucial for maintaining the integrity of vaulted ceilings.

在建筑术语中，拱形稳定性 arch stability 对于维持拱形天花板的完整性至关重要。

3.To improve the arch stability 拱形稳定性 of the structure, engineers used reinforced materials.

为了提高结构的拱形稳定性 arch stability，工程师使用了加固材料。

4.During the inspection, we found that the arch stability 拱形稳定性 of the old bridge had deteriorated over time.

在检查过程中，我们发现这座旧桥的拱形稳定性 arch stability随着时间的推移而恶化。

5.The ancient Roman aqueducts are a testament to the importance of arch stability 拱形稳定性 in construction.

古罗马的渡槽证明了建筑中拱形稳定性 arch stability的重要性。

作文

The concept of arch stability is fundamental in the field of structural engineering and architecture. It refers to the ability of an arch to maintain its shape and support loads without collapsing. The design of arches has been a critical aspect of construction for centuries, from ancient Roman aqueducts to modern bridges. Understanding arch stability is essential for engineers and architects to ensure that their structures can withstand various forces, including gravity, wind, and seismic activity.An arch functions by distributing weight across its curve, allowing it to support heavy loads while minimizing material use. The key to achieving arch stability lies in the geometry of the arch itself. A well-designed arch will have a specific shape and dimensions that enhance its ability to bear weight. For instance, a semicircular arch is known for its strength and stability because it evenly distributes the load along its curve.Another important factor in arch stability is the materials used in construction. Traditional materials like stone and brick were often employed in the construction of arches due to their compressive strength. However, modern engineering has introduced new materials such as reinforced concrete and steel, which can further enhance the stability and durability of arches. Engineers must carefully select materials based on the specific requirements of each project to ensure optimal arch stability.In addition to the design and materials, environmental factors also play a crucial role in the stability of arches. For example, changes in temperature can cause materials to expand or contract, potentially affecting the integrity of the structure. Similarly, weather conditions such as heavy rainfall or snow accumulation can increase the load on an arch, necessitating careful consideration during the design phase. Engineers must take these factors into account to maintain arch stability over time.Moreover, the location of an arch is significant in determining its stability. Arches built in areas prone to earthquakes or high winds must be designed with additional reinforcements to ensure they remain stable under extreme conditions. This requires a thorough understanding of the local environment and potential hazards that could impact the structure's integrity.In conclusion, arch stability is a vital aspect of engineering and architecture that ensures the safety and longevity of structures. By focusing on the design, materials, environmental factors, and location, engineers can create arches that not only serve their intended purpose but also stand the test of time. As we continue to innovate and explore new building techniques, the principles of arch stability will remain essential in shaping the skylines of our cities and the infrastructure of our communities. It is through this understanding that we can appreciate the beauty and functionality of arches in our built environment, recognizing their significance in both historical and modern contexts.

“拱形稳定性”这一概念在结构工程和建筑领域中至关重要。它指的是拱形结构在不倒塌的情况下保持其形状并支撑负载的能力。拱形设计在建筑中已经是一个关键方面，历经数百年，从古罗马的水道到现代的桥梁。理解“拱形稳定性”对于工程师和建筑师来说至关重要，以确保他们的结构能够承受重力、风力和地震活动等各种力量。拱形通过沿其曲线分配重量的方式运作，使其能够在最小化材料使用的同时支撑重负荷。实现“拱形稳定性”的关键在于拱形本身的几何形状。一个设计良好的拱形将具有特定的形状和尺寸，以增强其承载重量的能力。例如，半圆形拱因其均匀分配负载而以其强度和稳定性而闻名。影响“拱形稳定性”的另一个重要因素是建筑中使用的材料。传统材料如石材和砖块常用于拱形结构的建造，因为它们具有抗压强度。然而，现代工程引入了新材料，如钢筋混凝土和钢材，这可以进一步增强拱形的稳定性和耐久性。工程师必须根据每个项目的具体要求仔细选择材料，以确保最佳的“拱形稳定性”。除了设计和材料，环境因素在拱形的稳定性中也起着至关重要的作用。例如，温度变化可能导致材料膨胀或收缩，从而可能影响结构的完整性。同样，恶劣天气条件如大雨或积雪可能会增加拱形上的负载，因此在设计阶段需要仔细考虑。工程师必须考虑这些因素，以保持“拱形稳定性”。此外，拱形的位置在确定其稳定性方面也很重要。建造在易发生地震或强风地区的拱形必须设计有额外的加固，以确保它们在极端条件下保持稳定。这需要对当地环境及可能影响结构完整性的潜在危险有深入了解。总之，“拱形稳定性”是工程和建筑中的一个重要方面，确保结构的安全性和持久性。通过关注设计、材料、环境因素和位置，工程师可以创建不仅能满足其预期用途而且能够经受时间考验的拱形。随着我们继续创新并探索新的建筑技术，“拱形稳定性”的原则将在塑造城市天际线和社区基础设施中继续发挥重要作用。正是通过这种理解，我们才能欣赏拱形在我们建筑环境中的美与功能，认识到它们在历史和现代背景中的重要性。