anchorage force

简明释义

锚定力

英英释义

例句

1.The anchorage force must be properly distributed to avoid structural failure.

必须合理分配锚固力以避免结构失效。

2.The engineer calculated the anchorage force to ensure the structure would withstand strong winds.

工程师计算了锚固力以确保结构能够抵御强风。

3.The architect specified the required anchorage force for the new high-rise building.

建筑师为新的高层建筑指定了所需的锚固力。

4.During the testing phase, we monitored the anchorage force to assess the safety of the design.

在测试阶段，我们监测了锚固力以评估设计的安全性。

5.In bridge construction, understanding the anchorage force is crucial for stability.

在桥梁建设中，理解锚固力对稳定性至关重要。

作文

The term anchorage force refers to the force that is exerted by an anchor to hold a structure in place, particularly in engineering and construction contexts. This concept is crucial in ensuring the stability and safety of various structures, including bridges, buildings, and offshore platforms. In civil engineering, understanding the dynamics of anchorage force is essential for designing safe and durable constructions.When we think about the role of an anchor, we often imagine a simple object that keeps boats in place. However, the reality is much more complex. The anchorage force is not just a static force; it is influenced by numerous factors such as the weight of the structure, environmental conditions, and the materials used. For example, in bridge construction, engineers must calculate the anchorage force to ensure that the cables can withstand the load of the bridge and any additional forces like wind or seismic activity.Moreover, the anchorage force plays a significant role in the design of retaining walls. These walls are built to hold back soil and prevent erosion. Engineers must consider the lateral earth pressure and how the anchorage force will counteract this pressure to maintain the wall's integrity. Without proper calculation and implementation of the anchorage force, structures could fail, leading to catastrophic consequences.In the context of offshore platforms, the anchorage force becomes even more critical due to the harsh marine environment. The anchors must be designed to resist not only the weight of the platform but also the dynamic forces from waves and currents. Engineers use advanced modeling techniques to predict how the anchorage force will behave under different conditions, ensuring that the platform remains stable and secure throughout its operational life.Additionally, the understanding of anchorage force extends beyond traditional construction. In the field of rock climbing, climbers rely on anchors to secure themselves to the rock face. The anchorage force here is vital for safety, as it determines whether the anchor will hold under the climber's weight. Climbers must choose their anchors wisely, considering the rock quality and the direction of the force applied.In conclusion, the concept of anchorage force is fundamental across various fields, from civil engineering to recreational activities like climbing. It encompasses a range of forces and requires careful consideration in design and implementation. By mastering the principles surrounding anchorage force, engineers and climbers alike can ensure safety and stability in their respective domains. Understanding this term not only enhances our knowledge of structural integrity but also highlights the importance of meticulous planning and execution in any project involving anchoring systems.Overall, the study of anchorage force is a testament to the intricate relationship between physics and engineering, showcasing how fundamental concepts can have far-reaching applications in our world.

“锚固力”这一术语指的是锚在保持结构稳定时施加的力，尤其是在工程和建筑领域。这个概念对于确保各种结构的稳定性和安全性至关重要，包括桥梁、建筑物和海上平台。在土木工程中，理解“锚固力”的动态特性对于设计安全且耐用的建筑至关重要。当我们想到锚的作用时，常常会想象一个简单的物体，它使船只保持在原地。然而，现实要复杂得多。“锚固力”不仅仅是一个静态的力量；它受到许多因素的影响，例如结构的重量、环境条件和所使用的材料。例如，在桥梁建设中，工程师必须计算“锚固力”，以确保电缆能够承受桥梁的负荷以及任何额外的力量，如风或地震活动。此外，“锚固力”在挡土墙的设计中也发挥着重要作用。这些墙体是为了阻止土壤流失而建造的。工程师必须考虑侧向土压力，以及“锚固力”如何抵消这种压力，以维持墙体的完整性。如果没有对“锚固力”的正确计算和实施，结构可能会失败，导致灾难性的后果。在海上平台的背景下，“锚固力”变得更加关键，因为海洋环境恶劣。锚必须设计成不仅能抵抗平台的重量，还能抵御波浪和水流带来的动态力量。工程师使用先进的建模技术来预测“锚固力”在不同条件下的表现，确保平台在其运营生命周期内保持稳定和安全。此外，“锚固力”的理解不仅限于传统建筑。在攀岩领域，攀岩者依赖锚将自己固定在岩壁上。这里的“锚固力”对安全至关重要，因为它决定了锚在攀岩者重量下是否会保持稳定。攀岩者必须明智地选择他们的锚，考虑岩石质量和施加力量的方向。总之，“锚固力”这一概念在各个领域都是基础，从土木工程到攀岩等休闲活动。它涵盖了一系列的力量，并需要在设计和实施中仔细考虑。通过掌握有关“锚固力”的原则，工程师和攀岩者可以确保各自领域的安全和稳定。理解这个术语不仅增强了我们对结构完整性的认识，也突显了在任何涉及锚固系统的项目中精心规划和执行的重要性。总体而言，对“锚固力”的研究证明了物理学与工程学之间错综复杂的关系，展示了基本概念在我们世界中的广泛应用。