bottom longitudinal

简明释义

1. 底部纵材; 2. 底部纵骨;

英英释义

例句

1.The engineer designed the frame with a strong bottom longitudinal 底部纵向 support to enhance stability.

工程师设计了一个强大的底部纵向 底部纵向支撑，以增强稳定性。

2.During the inspection, we found that the bottom longitudinal 底部纵向 beams were improperly aligned.

在检查过程中，我们发现底部纵向 底部纵向梁的对齐不当。

3.The structural integrity of the bridge relies heavily on its bottom longitudinal 底部纵向 components.

桥梁的结构完整性在很大程度上依赖于其底部纵向 底部纵向组件。

4.The design specifications call for a minimum thickness for the bottom longitudinal 底部纵向 members.

设计规范要求底部纵向 底部纵向构件的最小厚度。

5.We need to reinforce the bottom longitudinal 底部纵向 section before the heavy load is applied.

在施加重载之前，我们需要加固底部纵向 底部纵向部分。

作文

In the field of engineering and design, understanding various dimensions and orientations is crucial for creating functional and efficient products. One such term that often arises in discussions about structural integrity is bottom longitudinal. The phrase refers to a specific orientation or alignment within a structure, particularly focusing on the lower part that runs along the length of an object. This concept is essential when analyzing forces, stresses, and overall stability in various applications, from bridges to buildings and even in smaller items like furniture. When engineers design a bridge, they must consider how weight will be distributed across the structure. The bottom longitudinal elements of the bridge play a significant role in supporting the load. These components are typically positioned at the lowest point of the bridge's framework, extending from one end to the other, thereby providing a stable base. By understanding the bottom longitudinal aspect, engineers can ensure that the bridge can withstand not only its own weight but also the additional weight of vehicles and pedestrians. Moreover, the significance of bottom longitudinal components extends beyond just bridges; it is equally important in the construction of buildings. In multi-story structures, the foundation often includes bottom longitudinal beams that help distribute the weight of the building evenly. This distribution is vital for preventing structural failure, especially in areas prone to earthquakes or heavy winds. Engineers use advanced materials and design techniques to enhance the strength of these bottom longitudinal supports, ensuring that they can handle both static and dynamic loads. In the world of furniture design, the concept of bottom longitudinal is also relevant. For instance, when creating a sturdy table, designers must consider the placement of support beams along the bottom of the table. These beams, which run longitudinally, provide stability and prevent the table from wobbling. If the bottom longitudinal supports are not adequately designed, the table might collapse under pressure or become unbalanced, leading to potential accidents. Understanding the implications of bottom longitudinal structures is not limited to just physical products; it also has applications in theoretical models and simulations. Engineers often use computer-aided design (CAD) software to visualize how bottom longitudinal elements interact with other parts of a structure. By simulating different scenarios, they can predict how changes in these components might affect overall performance and safety. As technology advances, the materials used for bottom longitudinal supports are evolving as well. New composites and alloys are being developed to provide greater strength while reducing weight. This innovation allows for more creative designs without compromising safety. For example, in aerospace engineering, the bottom longitudinal components of an aircraft must be lightweight yet incredibly strong to withstand the forces encountered during flight. In conclusion, the term bottom longitudinal encapsulates a critical aspect of engineering and design that affects a wide range of structures and products. From bridges and buildings to furniture and aircraft, the proper understanding and implementation of bottom longitudinal elements are vital for ensuring safety, stability, and functionality. As we continue to innovate and push the boundaries of design, the importance of these foundational elements will remain a key focus for engineers and designers alike.

在工程和设计领域，理解各种尺寸和方向对于创造功能性和高效的产品至关重要。一个经常出现在关于结构完整性的讨论中的术语是bottom longitudinal。这个短语指的是结构中一种特定的方向或对齐方式，特别关注沿着物体长度延伸的下部。这一概念在分析力、应力和各种应用中的整体稳定性时至关重要，从桥梁到建筑物，甚至在像家具这样的小物件中也是如此。当工程师设计桥梁时，他们必须考虑重量如何在结构中分布。bottom longitudinal元素在支撑负载方面发挥着重要作用。这些组件通常位于桥梁框架的最低点，从一端延伸到另一端，从而提供一个稳定的基础。通过理解bottom longitudinal的方面，工程师可以确保桥梁不仅能够承受自身的重量，还能承受车辆和行人的额外重量。此外，bottom longitudinal组件的重要性不仅限于桥梁；在建筑物的构造中同样重要。在多层结构中，基础通常包括bottom longitudinal梁，这些梁有助于均匀分配建筑物的重量。这样的分配对于防止结构失效至关重要，尤其是在易发生地震或强风的地区。工程师使用先进的材料和设计技术来增强这些bottom longitudinal支撑的强度，确保它们能够承受静态和动态负荷。在家具设计的世界中，bottom longitudinal的概念同样相关。例如，在创建一个坚固的桌子时，设计师必须考虑沿桌子底部放置支撑梁。这些沿纵向延伸的梁提供了稳定性，并防止桌子摇晃。如果bottom longitudinal支撑设计不当，桌子可能会在压力下倒塌或失去平衡，从而导致潜在的事故。理解bottom longitudinal结构的影响不仅限于物理产品；它在理论模型和模拟中也有应用。工程师经常使用计算机辅助设计（CAD）软件来可视化bottom longitudinal元素如何与结构的其他部分相互作用。通过模拟不同的场景，他们可以预测这些组件的变化如何影响整体性能和安全性。随着技术的发展，用于bottom longitudinal支撑的材料也在不断演变。新的复合材料和合金正在开发，以提供更大的强度，同时减轻重量。这种创新允许在不妥协安全性的情况下进行更具创意的设计。例如，在航空航天工程中，飞机的bottom longitudinal组件必须轻便且极其坚固，以承受飞行过程中遇到的力量。总之，术语bottom longitudinal概括了工程和设计中一个关键方面，这影响着广泛的结构和产品。从桥梁和建筑物到家具和飞机，正确理解和实施bottom longitudinal元素对于确保安全、稳定和功能性至关重要。随着我们继续创新并推动设计的界限，这些基础元素的重要性将始终是工程师和设计师的重点。