concave bending of frame

简明释义

骨材内弯

英英释义

例句

1.The architect designed the structure to accommodate the concave bending of frame to enhance its aesthetic appeal.

建筑师设计了这个结构，以适应框架的凹曲，以增强其美学吸引力。

2.Engineers must account for the concave bending of frame when calculating load distributions in bridges.

工程师在计算桥梁的荷载分布时必须考虑框架的凹曲。

3.During the inspection, we noticed significant concave bending of frame which could affect the building's integrity.

在检查过程中，我们注意到显著的框架的凹曲，这可能会影响建筑的完整性。

4.In furniture design, concave bending of frame can provide both strength and elegance.

在家具设计中，框架的凹曲可以提供强度和优雅感。

5.The artist used concave bending of frame to create a unique visual effect in the sculpture.

艺术家利用框架的凹曲在雕塑中创造出独特的视觉效果。

作文

In the field of engineering and architecture, understanding the various types of structural deformations is crucial. One such deformation that often arises in the design and analysis of frames is the concave bending of frame. This term refers to a specific type of bending where the frame curves inward, creating a concave shape. This phenomenon can occur due to various factors, including applied loads, material properties, and the geometric configuration of the structure. When engineers design frames, they must consider how these structures will respond to different forces. For instance, when a load is applied to a beam within a frame, it may cause the beam to bend. If the bending results in a concave shape, this can lead to significant implications for the overall stability and integrity of the structure. The concave bending of frame can result in increased stress concentrations in certain areas, which may lead to potential failure if not properly accounted for during the design phase.Moreover, the concave bending of frame can affect the aesthetic appeal of a structure. Architects often aim to create visually pleasing designs that also serve their functional purposes. However, if a frame bends concavely, it may alter the intended appearance of the building or structure. Therefore, understanding this bending behavior is essential not only for safety but also for achieving the desired architectural vision.To analyze the concave bending of frame, engineers utilize various methods, including finite element analysis (FEA). This computational technique allows for a detailed examination of how frames will behave under different loading conditions. By simulating the effects of loads on a frame, engineers can predict the extent of concave bending and make necessary adjustments to the design. This ensures that the structure can withstand the expected forces without compromising its performance or safety.In addition to structural analysis, material selection plays a vital role in addressing the concave bending of frame. Different materials exhibit varying degrees of flexibility and strength. For example, steel frames are known for their high strength-to-weight ratio, making them suitable for applications where concave bending might be a concern. On the other hand, materials like wood may experience more significant bending under similar loads, necessitating careful consideration in the design process.In conclusion, the concave bending of frame is a critical concept in engineering and architecture that encompasses both structural integrity and aesthetic considerations. By understanding the mechanisms behind this type of bending, engineers and architects can create safer, more efficient, and visually appealing structures. Whether through advanced analytical techniques or careful material selection, addressing the challenges posed by concave bending is essential for the success of any construction project.

在工程和建筑领域，理解各种结构变形是至关重要的。其中一种常见的变形是在框架的设计和分析中出现的框架的凹弯。这个术语指的是一种特定类型的弯曲，其中框架向内弯曲，形成一个凹形。这种现象可能由于多种因素引起，包括施加的载荷、材料特性和结构的几何配置。当工程师设计框架时，他们必须考虑这些结构在不同力作用下的反应。例如，当载荷施加到框架中的梁上时，可能会导致梁弯曲。如果弯曲导致凹形，这可能对结构的整体稳定性和完整性产生重大影响。框架的凹弯可能导致某些区域的应力集中增加，如果在设计阶段没有妥善考虑，可能会导致潜在的失效。此外，框架的凹弯还会影响结构的美观。建筑师通常旨在创造既美观又实用的设计。然而，如果框架向内弯曲，可能会改变建筑或结构的预期外观。因此，理解这种弯曲行为对于确保安全和实现所需的建筑愿景至关重要。为了分析框架的凹弯，工程师采用各种方法，包括有限元分析（FEA）。这种计算技术允许详细检查框架在不同加载条件下的行为。通过模拟载荷对框架的影响，工程师可以预测凹弯的程度，并对设计进行必要的调整。这确保了结构能够承受预期的力，而不影响其性能或安全性。除了结构分析，材料选择在解决框架的凹弯问题中也起着至关重要的作用。不同材料表现出不同程度的柔韧性和强度。例如，钢框架以其高强度重量比而闻名，适合于可能存在凹弯问题的应用。另一方面，木材在类似载荷下可能会经历更显著的弯曲，因此在设计过程中需要谨慎考虑。总之，框架的凹弯是工程和建筑中一个关键概念，涵盖了结构完整性和美学考虑。通过理解这种弯曲背后的机制，工程师和建筑师可以创造出更安全、更高效且更具视觉吸引力的结构。无论是通过先进的分析技术还是精心的材料选择，解决凹弯带来的挑战对于任何建设项目的成功都是至关重要的。