immersed transom beam

简明释义

设计水线处尾板宽度

英英释义

例句

1.During the inspection, the immersed transom beam was found to have some corrosion issues.

在检查中，发现浸没横梁存在一些腐蚀问题。

2.The engineers designed the structure to support the weight of the water above the immersed transom beam.

工程师设计了结构以支撑水面上方的浸没横梁的重量。

3.We need to calculate the load distribution on the immersed transom beam for safety purposes.

我们需要计算浸没横梁上的荷载分布以确保安全。

4.The stability of the boat depends largely on the design of the immersed transom beam.

船只的稳定性在很大程度上取决于浸没横梁的设计。

5.An effective maintenance plan should include regular checks of the immersed transom beam.

有效的维护计划应包括定期检查浸没横梁。

作文

In the field of civil engineering, particularly when dealing with structures that require stability and strength, the concept of an immersed transom beam becomes crucial. An immersed transom beam refers to a horizontal structural element that is submerged or placed below the water level, often used in bridges, docks, and other waterfront constructions. These beams play a vital role in distributing loads and enhancing the overall integrity of the structure. The design and implementation of an immersed transom beam involve careful consideration of various factors, including hydrodynamic forces, material selection, and environmental conditions. For instance, when a bridge spans over a river, the immersed transom beam must withstand not only the weight of the vehicles that will traverse it but also the constant pressure exerted by the flowing water beneath. This requires engineers to conduct thorough analyses to ensure that the beam can handle both static and dynamic loads. One of the significant advantages of using an immersed transom beam is its ability to provide enhanced stability to structures in aquatic environments. Since these beams are submerged, they can effectively counteract the forces of buoyancy and wave action, which are critical considerations in marine engineering. Moreover, they can be designed to minimize the impact of erosion caused by water currents, thereby prolonging the lifespan of the structure. Another important aspect of immersed transom beams is their construction materials. Engineers often opt for reinforced concrete or steel due to their high tensile strength and durability. The choice of materials is influenced by factors such as cost, availability, and the specific requirements of the project. For example, in areas prone to corrosion, special coatings or corrosion-resistant materials may be utilized to protect the immersed transom beam from degradation over time. In addition to their structural benefits, immersed transom beams can also contribute to the aesthetic appeal of a construction project. When designed thoughtfully, these beams can blend seamlessly with their surroundings, creating a visually pleasing environment while maintaining functionality. For instance, in waterfront parks or recreational areas, immersed transom beams can be integrated into walkways or viewing platforms, enhancing both the user experience and the structural design. Furthermore, the use of immersed transom beams aligns with sustainable engineering practices. By utilizing materials that are environmentally friendly and designing structures that minimize disruption to aquatic ecosystems, engineers can create solutions that not only meet human needs but also protect natural habitats. This balance between development and conservation is increasingly important in today’s world, where environmental concerns are at the forefront of engineering practices. In conclusion, the immersed transom beam is a fundamental component in the design and construction of various structures, particularly those situated in water. Its ability to provide stability, withstand environmental forces, and contribute to aesthetic and sustainable practices makes it an essential element in modern engineering. As we continue to advance in this field, understanding and mastering the intricacies of immersed transom beams will be vital for future projects that aim to harmonize human infrastructure with the natural world.

在土木工程领域，特别是在处理需要稳定性和强度的结构时，浸入式横梁的概念变得至关重要。浸入式横梁是指一个水平结构元件，它被浸没或放置在水面以下，通常用于桥梁、码头及其他水边建筑。这些梁在分配负载和增强结构整体完整性方面发挥着重要作用。设计和实施浸入式横梁时，需要仔细考虑各种因素，包括水动力学力、材料选择和环境条件。例如，当一座桥跨越一条河流时，浸入式横梁不仅必须承受通行车辆的重量，还必须承受流动水下施加的持续压力。这要求工程师进行全面分析，以确保该梁能够承受静态和动态负载。使用浸入式横梁的一个显著优势是它能够为水域环境中的结构提供增强的稳定性。由于这些梁是浸没的，它们可以有效抵消浮力和波浪作用的力量，这在海洋工程中是关键考虑因素。此外，它们可以设计成最小化水流造成的侵蚀影响，从而延长结构的使用寿命。浸入式横梁的另一个重要方面是其施工材料。工程师通常选择钢筋混凝土或钢材，因为它们具有高抗拉强度和耐久性。材料的选择受到成本、可用性和项目具体要求等因素的影响。例如，在易腐蚀的地区，可能会使用特殊涂层或耐腐蚀材料来保护浸入式横梁免于随时间退化。除了结构上的好处外，浸入式横梁还可以提升建筑项目的美观性。当经过精心设计时，这些梁可以与周围环境无缝融合，创造出既美观又功能齐全的环境。例如，在水边公园或休闲区，浸入式横梁可以集成到人行道或观景平台中，增强用户体验和结构设计。此外，使用浸入式横梁符合可持续工程实践。通过利用环保材料和设计出最小化对水生生态系统干扰的结构，工程师可以创建满足人类需求同时保护自然栖息地的解决方案。这种发展与保护之间的平衡在当今世界愈发重要，因为环境问题已成为工程实践的重点。总之，浸入式横梁是各种结构设计和施工中的基本组成部分，特别是那些位于水中的结构。它提供稳定性、承受环境力量以及促进美观和可持续实践的能力，使其成为现代工程的一个重要元素。随着我们在这一领域的不断进步，理解和掌握浸入式横梁的复杂性将对未来旨在协调人类基础设施与自然世界的项目至关重要。