structure irregularity

简明释义

结构不规则性

英英释义

例句

1.In our recent study, we found a significant structure irregularity 结构不规则性 in the geological survey results.

在我们最近的研究中，我们发现地质勘查结果中存在显著的结构不规则性结构不规则性。

2.The contractor was alerted to a structure irregularity 结构不规则性 during the construction process that could lead to structural failure.

承包商在施工过程中被提醒存在一个可能导致结构失效的结构不规则性结构不规则性。

3.The architect revised the plans after identifying a structure irregularity 结构不规则性 that could affect the aesthetic appeal of the building.

建筑师在识别出一个可能影响建筑美观的结构不规则性结构不规则性后，修改了计划。

4.The engineers discovered a structure irregularity 结构不规则性 in the bridge design that could compromise its safety.

工程师在桥梁设计中发现了一个结构不规则性结构不规则性，这可能会危及其安全。

5.During the inspection, we noted a structure irregularity 结构不规则性 in the building's foundation that required immediate attention.

在检查过程中，我们注意到建筑基础中存在一个结构不规则性结构不规则性，需要立即处理。

作文

In the field of architecture and engineering, the term structure irregularity refers to deviations from a regular or expected design in a building or structure. These deviations can manifest in various forms, such as uneven load distribution, unexpected shapes, or variations in material properties. Understanding structure irregularity is crucial for engineers and architects as it directly impacts the stability, safety, and durability of a structure. When designing a building, architects typically aim for symmetry and uniformity to ensure that loads are evenly distributed across the structure. However, real-world conditions often lead to structure irregularity. For example, a building might have an asymmetrical layout due to site constraints or aesthetic choices. This can create challenges during the construction phase and require careful consideration of how forces will be transmitted through the structure.One common type of structure irregularity is vertical irregularity, which occurs when floors are not aligned vertically. This can happen if a building has varying heights on different floors or if there are setbacks that alter the vertical alignment. Vertical irregularities can lead to increased stress on certain structural elements, making them more susceptible to failure during events such as earthquakes.Another form of structure irregularity is horizontal irregularity, which involves the plan shape of the structure. Buildings with L-shaped or U-shaped footprints may experience uneven loading, especially if they are subjected to lateral forces like wind or seismic activity. Engineers must analyze these irregularities to design appropriate reinforcement strategies that ensure the structure can withstand such forces without collapsing.Additionally, structure irregularity can arise from the use of different materials in a single structure. For instance, combining steel and concrete may introduce irregularities due to their differing properties. Steel has a high tensile strength but can be prone to buckling, while concrete is strong in compression but weak in tension. When these materials are used together without proper consideration of their interactions, it can lead to unexpected failures.To mitigate the risks associated with structure irregularity, engineers employ various techniques. One approach is to conduct thorough analysis and simulations to predict how a structure will behave under different loading conditions. Advanced software allows for the modeling of complex geometries and materials, enabling engineers to identify potential weaknesses before construction begins.Moreover, retrofitting existing structures with structure irregularity can enhance their resilience. This may involve adding braces, reinforcing walls, or even completely redesigning certain sections to improve load distribution. These interventions can significantly extend the life of a building and ensure it meets modern safety standards.In conclusion, structure irregularity is an essential concept in architecture and engineering that highlights the complexities involved in designing safe and durable buildings. By understanding and addressing these irregularities, professionals can create structures that not only meet aesthetic and functional requirements but also stand the test of time and natural forces. As our cities continue to evolve and grow, the importance of recognizing and managing structure irregularity will only increase, ensuring that we build a safer future for all.

在建筑和工程领域，术语结构不规则性指的是建筑或结构设计中偏离常规或预期设计的情况。这些偏差可以以多种形式表现出来，例如不均匀的荷载分布、意外的形状或材料特性的变化。理解结构不规则性对于工程师和建筑师至关重要，因为它直接影响到结构的稳定性、安全性和耐久性。在设计建筑时，建筑师通常追求对称性和均匀性，以确保荷载能够均匀分布在结构上。然而，现实世界中的条件往往导致结构不规则性。例如，由于场地限制或美学选择，建筑可能具有不对称的布局。这在施工阶段可能会带来挑战，需要仔细考虑力如何通过结构传递。一种常见的结构不规则性是垂直不规则性，它发生在楼层没有垂直对齐时。如果建筑的不同楼层高度各异，或者有退缩改变了垂直对齐，就会发生这种情况。垂直不规则性可能导致某些结构元素承受更大的应力，使其在地震等事件中更容易发生故障。另一种结构不规则性是水平不规则性，涉及到结构的平面形状。具有L形或U形底面的建筑在承受侧向力（如风或地震活动）时可能会经历不均匀的荷载。工程师必须分析这些不规则性，以设计合适的加固策略，确保结构在不倒塌的情况下能够承受这些力量。此外，结构不规则性还可能由于在单一结构中使用不同材料而产生。例如，结合钢材和混凝土可能会因其不同的特性而引入不规则性。钢材具有较高的抗拉强度，但容易屈曲，而混凝土在压缩上强大，但在拉伸上较弱。当这些材料结合使用而未能充分考虑它们的相互作用时，可能会导致意想不到的故障。为了减轻与结构不规则性相关的风险，工程师采用各种技术。一种方法是进行全面的分析和模拟，以预测结构在不同荷载条件下的行为。先进的软件允许对复杂几何形状和材料进行建模，使工程师能够在施工开始之前识别潜在的薄弱环节。此外，对现有具有结构不规则性的建筑进行加固可以增强其韧性。这可能涉及添加支撑、加固墙体，甚至完全重新设计某些部分，以改善荷载分布。这些干预措施可以显著延长建筑的使用寿命，并确保其符合现代安全标准。总之，结构不规则性是建筑和工程中的一个重要概念，突显了在设计安全和耐用建筑过程中所涉及的复杂性。通过理解和解决这些不规则性，专业人员可以创建不仅满足美学和功能要求的结构，还能经受住时间和自然力量的考验。随着我们的城市不断发展壮大，认识和管理结构不规则性的重要性只会增加，确保我们为所有人建设一个更安全的未来。