transverse stiffener

简明释义

横向防挠材

英英释义

例句

1.During the fabrication process, the transverse stiffener was welded to the main structure for added stability.

在制造过程中，横向加劲肋被焊接到主结构上以增加稳定性。

2.The engineer specified that each beam should include a transverse stiffener to enhance its load-bearing capacity.

工程师规定每根梁应包括一个横向加劲肋以增强其承载能力。

3.To prevent buckling, the design included multiple transverse stiffeners along the length of the panel.

为防止屈曲，设计中在面板的长度方向上包括多个横向加劲肋。

4.In the bridge design, the transverse stiffeners were crucial for maintaining the integrity of the deck.

在桥梁设计中，横向加劲肋对保持桥面完整性至关重要。

5.The transverse stiffener helps distribute loads evenly across the structure, minimizing stress concentrations.

横向加劲肋有助于均匀分配结构上的荷载，最小化应力集中。

作文

In the field of structural engineering, the role of various components is crucial for ensuring the stability and integrity of a structure. One such component that often goes unnoticed is the transverse stiffener. A transverse stiffener (横向加劲肋) is a vital element used in beams and plates to enhance their resistance to bending and buckling. By providing additional support across the width of the structure, these stiffeners play a significant role in maintaining the overall strength and durability of the construction. The primary function of a transverse stiffener is to distribute loads more evenly across the structural element. When a beam or plate is subjected to external forces, it experiences bending moments that can lead to deformation. Without adequate stiffening, these deformations can compromise the structural integrity, potentially leading to failure. The introduction of a transverse stiffener helps to mitigate this risk by reinforcing the element against lateral forces. Moreover, transverse stiffeners are particularly important in large structures such as bridges, ships, and buildings where the dimensions and loads can be substantial. In these applications, the design and placement of transverse stiffeners must be carefully considered to ensure optimal performance. For instance, the spacing and size of the stiffeners will vary depending on the specific requirements of the project, including the materials used and the expected load conditions. In addition to their structural benefits, transverse stiffeners also contribute to the aesthetic aspects of a design. When incorporated thoughtfully, they can enhance the visual appeal of a structure while still serving their functional purpose. Engineers and architects often collaborate to create solutions that balance both aesthetics and structural integrity, showcasing how elements like transverse stiffeners can be seamlessly integrated into the overall design. Furthermore, advancements in technology have led to improved methods for analyzing and optimizing the use of transverse stiffeners. Computer-aided design (CAD) software allows engineers to simulate various load scenarios and assess the effectiveness of different stiffener configurations. This capability not only saves time during the design process but also results in safer and more efficient structures. In conclusion, the significance of the transverse stiffener (横向加劲肋) cannot be overstated in the realm of structural engineering. Its ability to enhance the strength and stability of beams and plates makes it an indispensable component in many construction projects. As we continue to innovate and improve our building techniques, understanding the roles of such elements will be essential for future developments in the industry. Whether in large-scale infrastructure or smaller architectural designs, the thoughtful application of transverse stiffeners will undoubtedly play a key role in shaping the structures of tomorrow.