reinforcing rib

简明释义

加强筋

英英释义

例句

1.The design of the aircraft wing includes several reinforcing ribs to withstand aerodynamic forces.

飞机机翼的设计包括几个加固肋以承受气动力。

2.The structural engineer emphasized the importance of the reinforcing rib in maintaining the integrity of the bridge.

结构工程师强调了加固肋在维护桥梁完整性方面的重要性。

3.The architect specified that each panel should have a reinforcing rib to prevent warping over time.

建筑师规定每个面板都应有一个加固肋以防止随着时间的推移而变形。

4.During the construction, they added a reinforcing rib to enhance the strength of the concrete slab.

在施工过程中，他们添加了一个加固肋以增强混凝土板的强度。

5.In the automotive industry, a well-placed reinforcing rib can significantly improve the durability of car parts.

在汽车工业中，合理放置的加固肋可以显著提高汽车零部件的耐用性。

作文

In the world of engineering and architecture, the concept of structural integrity is paramount. One of the critical components that contribute to this integrity is the use of elements known as reinforcing ribs. These are structural features that provide additional strength and support to various materials, particularly in constructions that require enhanced durability and stability. The reinforcing rib can be found in numerous applications, ranging from bridges and buildings to aircraft and automobiles. Understanding the role of these ribs can help us appreciate their importance in modern construction and design.The primary function of a reinforcing rib is to distribute loads and stresses more evenly across a structure. When forces are applied to a material, they can create points of weakness that may lead to failure. By incorporating reinforcing ribs, engineers can mitigate these risks by ensuring that the load is shared among multiple points, reducing the likelihood of cracks or breaks. For instance, in concrete structures, reinforcing ribs are often embedded within the concrete to enhance its tensile strength, which is crucial since concrete alone is strong under compression but weak under tension.Moreover, reinforcing ribs also play a significant role in improving the overall stiffness of a structure. Stiffness refers to the resistance of an object to deformation when subjected to external forces. In many cases, a structure must not only bear weight but also withstand forces such as wind, earthquakes, or vibrations. By adding reinforcing ribs, designers can increase the stiffness of beams, panels, and other components, making them more resilient to dynamic loads.Another important aspect of reinforcing ribs is their contribution to the lightweight design of structures. Engineers are often challenged to create strong yet lightweight components to improve fuel efficiency in vehicles and reduce material costs in buildings. By strategically placing reinforcing ribs, it is possible to achieve a higher strength-to-weight ratio, allowing for lighter designs without compromising safety or performance. This principle is especially evident in the aerospace industry, where every ounce counts, and reinforcing ribs are meticulously designed to provide maximum support with minimal weight.The application of reinforcing ribs extends beyond traditional materials like concrete and steel. In modern manufacturing processes, such as 3D printing and composite materials, reinforcing ribs can be integrated into designs from the very beginning, allowing for innovative shapes and structures that were previously impossible to achieve. This has opened up new possibilities in product design, enabling the creation of complex geometries that enhance both functionality and aesthetics.In conclusion, the significance of reinforcing ribs in engineering cannot be overstated. They are essential for enhancing the strength, stiffness, and overall performance of various structures. From the bridges we travel on to the airplanes we fly in, reinforcing ribs play a vital role in ensuring safety and reliability. As technology advances, the methods of incorporating reinforcing ribs will continue to evolve, leading to even more innovative and efficient designs that push the boundaries of what is possible in construction and manufacturing. Understanding and mastering the concept of reinforcing ribs is crucial for anyone involved in the fields of engineering and architecture, as it forms the backbone of structural design and integrity.

在工程和建筑的世界中，结构完整性的概念至关重要。影响这一完整性的关键组成部分之一是被称为增强肋的元素。这些是提供额外强度和支持的结构特征，特别是在需要增强耐久性和稳定性的建筑中。增强肋可以在许多应用中找到，从桥梁和建筑到飞机和汽车。理解这些肋的作用可以帮助我们欣赏它们在现代建筑和设计中的重要性。增强肋的主要功能是更均匀地分配负载和应力。当力量施加到材料上时，它们可能会产生薄弱点，导致失效。通过加入增强肋，工程师可以通过确保负载在多个点之间共享来减轻这些风险，从而减少裂缝或断裂的可能性。例如，在混凝土结构中，增强肋通常嵌入混凝土中，以增强其抗拉强度，这一点至关重要，因为混凝土本身在压缩下强大，但在拉伸下脆弱。此外，增强肋还在提高结构整体刚度方面发挥着重要作用。刚度是指物体在受到外部力量作用时抵抗变形的能力。在许多情况下，结构不仅必须承受重量，还必须抵抗风、地震或振动等力量。通过添加增强肋，设计师可以提高梁、面板和其他组件的刚度，使其对动态负载更具弹性。增强肋的另一个重要方面是它们对轻量化设计的贡献。工程师常常面临创造强大而轻便的组件以提高车辆燃油效率和降低建筑材料成本的挑战。通过战略性地放置增强肋，可以实现更高的强度与重量比，从而在不妨碍安全或性能的情况下实现更轻的设计。这一原则在航空航天工业中尤为明显，在这里每盎司都很重要，增强肋被精心设计以提供最大支持而最小的重量。增强肋的应用超越了传统的混凝土和钢材等材料。在现代制造过程中，如3D打印和复合材料，增强肋可以从一开始就融入设计，允许实现以前无法达到的创新形状和结构。这为产品设计开辟了新的可能性，使得创建增强功能和美学的复杂几何形状成为可能。总之，增强肋在工程中的重要性不容小觑。它们对于增强各种结构的强度、刚度和整体性能至关重要。从我们所行驶的桥梁到我们所乘坐的飞机，增强肋在确保安全和可靠性方面发挥着重要作用。随着技术的进步，整合增强肋的方法将继续演变，导致更具创新性和高效的设计，推动建筑和制造领域的可能性极限。理解和掌握增强肋的概念对任何参与工程和建筑领域的人来说都是至关重要的，因为它构成了结构设计和完整性的基础。