anchorage force

简明释义

1. 锚固力; 2. 支撑力; 3. 锚定力;

英英释义

例句

1.During the test, the team measured the anchorage force applied to the foundation.

在测试过程中，团队测量了施加于基础的锚固力。

2.The design included a safety factor for the anchorage force to enhance durability.

设计中包括了锚固力的安全系数，以增强耐久性。

3.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。

4.The engineer calculated the anchorage force to ensure the structure could withstand high winds.

工程师计算了锚固力以确保结构能够承受强风。

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 concept of anchorage force plays a crucial role in various fields, particularly in engineering and construction. It refers to the force that is exerted by an anchor to resist the movement of a structure or object. Understanding this force is essential for ensuring the stability and safety of buildings, bridges, and other infrastructures. In this essay, we will explore the significance of anchorage force in engineering, its applications, and how it contributes to the overall integrity of structures.To begin with, let us define what anchorage force entails. In simple terms, it is the force that holds an anchor in place, preventing it from being pulled out or moved by external forces such as wind, water, or seismic activity. This force is vital for structures that are subjected to dynamic loads, which can cause them to sway or shift. For example, in the case of a bridge, the anchorage force ensures that the bridge remains securely attached to its supports, even during strong winds or earthquakes.One of the primary applications of anchorage force is in the design of foundations. Engineers must calculate the necessary anchorage force to ensure that the foundation can withstand various forces acting upon it. This is especially important in areas prone to natural disasters, where the forces can be unpredictable and intense. By accurately determining the anchorage force, engineers can design foundations that provide adequate support and prevent catastrophic failures.Moreover, anchorage force is also critical in the installation of retaining walls. These walls are used to hold back soil and prevent erosion, and they rely on the anchorage force to maintain their position. If the anchorage force is insufficient, the retaining wall may collapse, leading to significant damage and safety hazards. Therefore, understanding the dynamics of anchorage force is key to ensuring the longevity and effectiveness of retaining structures.In addition to its role in static structures, anchorage force is also vital in the field of marine engineering. For instance, ships and offshore platforms use anchors to secure themselves to the seabed. The anchorage force generated by these anchors must be strong enough to resist the forces of waves, currents, and storms. Engineers must carefully assess the conditions of the seabed and the expected environmental loads to determine the appropriate anchor design and size.Furthermore, the study of anchorage force extends into the realm of safety and disaster management. For example, in the event of a natural disaster such as an earthquake or hurricane, the anchorage force of a building's foundation can mean the difference between survival and catastrophe. Buildings with inadequate anchorage forces may suffer severe damage or even collapse, while those designed with proper anchorage can withstand the forces and protect their occupants.In conclusion, the significance of anchorage force cannot be overstated. It is a fundamental concept in engineering that ensures the stability and safety of structures. From foundations to retaining walls and marine applications, understanding and calculating anchorage force is essential for successful design and construction. As we continue to face challenges posed by natural disasters and environmental changes, the role of anchorage force in engineering will remain a critical area of study and application, ensuring that our structures can endure the tests of time and nature.

“锚固力”这一概念在多个领域中扮演着至关重要的角色，尤其是在工程和建筑方面。它指的是锚对结构或物体施加的抵抗运动的力。理解这一力量对于确保建筑、桥梁和其他基础设施的稳定性和安全性至关重要。在这篇文章中，我们将探讨“锚固力”在工程中的重要性、其应用以及它如何有助于结构的整体完整性。首先，让我们定义一下“锚固力”的含义。简单来说，它是保持锚定位置的力量，防止其被外部力量（如风、水或地震活动）拉出或移动。这一力量对于受到动态载荷的结构至关重要，这些载荷可能会导致它们摇摆或位移。例如，在桥梁的情况下，“锚固力”确保桥梁在强风或地震期间仍然牢固地附着于支撑点。“锚固力”的主要应用之一是在基础设计中。工程师必须计算必要的锚固力，以确保基础能够承受各种作用于其上的力量。这在自然灾害频发的地区尤为重要，因为这些力量可能是不可预测且强烈的。通过准确确定“锚固力”，工程师可以设计出提供足够支持的基础，从而防止灾难性故障。此外，“锚固力”在挡土墙的安装中也至关重要。这些墙用于阻挡土壤并防止侵蚀，它们依赖于锚固力来维持其位置。如果“锚固力”不足，挡土墙可能会倒塌，导致重大损坏和安全隐患。因此，理解“锚固力”的动态特性对于确保挡土结构的耐久性和有效性至关重要。除了在静态结构中的作用外，“锚固力”在海洋工程领域也至关重要。例如，船舶和海上平台使用锚将自己固定在海底。这些锚产生的“锚固力”必须足够强大，以抵抗波浪、潮流和风暴的力量。工程师必须仔细评估海底条件和预期的环境负荷，以确定适当的锚设计和大小。此外，“锚固力”的研究还扩展到安全和灾害管理的领域。例如，在地震或飓风等自然灾害发生时，建筑物基础的“锚固力”可能意味着生存和灾难之间的区别。锚固力不足的建筑可能会遭受严重损坏甚至倒塌，而设计得当的建筑可以抵御这些力量，保护其居住者。总之，“锚固力”的重要性不容小觑。它是工程中的一个基本概念，确保结构的稳定性和安全性。从基础到挡土墙和海洋应用，理解和计算“锚固力”对于成功的设计和施工至关重要。随着我们继续面对自然灾害和环境变化带来的挑战，“锚固力”在工程中的作用将始终是一个关键的研究和应用领域，确保我们的结构能够经受时间和自然的考验。