concave bending of frame

简明释义

骨材内弯

英英释义

例句

1.The engineer explained how the concave bending of frame 框架的凹弯 could affect the overall stability of the structure.

工程师解释了< span>框架的凹弯如何影响结构的整体稳定性。

2.To improve performance, the team focused on reducing the concave bending of frame 框架的凹弯 during construction.

为了提高性能，团队专注于在施工过程中减少< span>框架的凹弯。

3.The architect suggested a redesign to minimize the concave bending of frame 框架的凹弯 in the new building.

建筑师建议重新设计，以最小化新建筑中< span>框架的凹弯。

4.In the design phase, we need to account for the concave bending of frame 框架的凹弯 to ensure proper load distribution.

在设计阶段，我们需要考虑< span>框架的凹弯以确保正确的负载分布。

5.During testing, the concave bending of frame 框架的凹弯 was observed under heavy loads.

在测试过程中，观察到< span>框架的凹弯在重载下的情况。

作文

The concept of concave bending of frame refers to a specific type of deformation that occurs in structural elements when they are subjected to external forces. In engineering and architecture, understanding how materials respond to stress is crucial for ensuring the safety and durability of structures. When a frame bends in a concave manner, it means that the inner side of the bend is facing towards the load, while the outer side is stretched. This phenomenon can be seen in various applications, from bridges to buildings, where the design must accommodate such bending to prevent failure.To illustrate the importance of concave bending of frame, consider a simple example of a bridge. Engineers must calculate the loads that the bridge will experience, including the weight of vehicles, pedestrians, and environmental factors like wind and snow. If the frame of the bridge is not designed to handle concave bending of frame, it may lead to structural weaknesses or even catastrophic failures. The materials used, such as steel or reinforced concrete, must have adequate tensile and compressive strength to withstand these forces without permanent deformation.Moreover, the design of frames that experience concave bending of frame requires careful consideration of geometry and material properties. For instance, a beam that is too slender may be more susceptible to bending than a thicker one. Engineers often use finite element analysis (FEA) to simulate how a frame will behave under various loading conditions, allowing them to optimize the design before construction begins.In addition to structural integrity, the aesthetic aspect of concave bending of frame cannot be overlooked. Architects often incorporate curves and bends into their designs to create visually appealing structures. The challenge lies in balancing beauty with functionality, ensuring that the frame can support the intended loads while also meeting the desired architectural vision.Furthermore, the study of concave bending of frame extends beyond traditional materials. With the advent of new technologies, engineers are exploring advanced materials such as composites and smart materials that can adapt to changing loads. These innovations may lead to frames that can better handle concave bending of frame without compromising on performance or safety.In conclusion, the concave bending of frame is a critical concept in the fields of engineering and architecture. It highlights the importance of understanding material behavior under stress and the need for thoughtful design to ensure structural integrity. As we continue to innovate and push the boundaries of design, the principles surrounding concave bending of frame will remain essential in creating safe, functional, and aesthetically pleasing structures.

框架的凹弯曲这一概念指的是在结构元件受到外力作用时发生的一种特定变形。在工程和建筑领域，理解材料对应力的反应对于确保结构的安全性和耐久性至关重要。当框架以凹形方式弯曲时，意味着弯曲的内侧面朝向负载，而外侧面则被拉伸。这一现象可以在各种应用中看到，从桥梁到建筑，设计必须考虑这种弯曲，以防止失效。为了说明凹弯曲的重要性，我们可以考虑一个简单的桥梁例子。工程师必须计算桥梁将经历的荷载，包括车辆、行人以及风雪等环境因素的重量。如果桥梁的框架没有设计成能够承受凹弯曲，可能会导致结构弱点甚至灾难性的失败。所使用的材料，如钢或钢筋混凝土，必须具有足够的抗拉和抗压强度，以承受这些力量而不产生永久性变形。此外，经历凹弯曲的框架设计需要仔细考虑几何形状和材料特性。例如，过于纤细的梁可能比较厚的梁更容易弯曲。工程师通常使用有限元分析（FEA）来模拟框架在各种加载条件下的行为，使他们能够在施工开始之前优化设计。除了结构完整性之外，凹弯曲的美学方面也不能被忽视。建筑师经常在设计中融入曲线和弯曲，以创造视觉上令人愉悦的结构。挑战在于平衡美观与功能性，确保框架能够支持预期的荷载，同时也满足所需的建筑愿景。此外，凹弯曲的研究超越了传统材料。随着新技术的出现，工程师正在探索复合材料和智能材料等先进材料，这些材料可以适应变化的荷载。这些创新可能导致能够更好地处理凹弯曲的框架，而不会妨碍性能或安全性。总之，凹弯曲是工程和建筑领域中的一个关键概念。它突出了理解材料在应力下的行为的重要性，以及为了确保结构完整性而需要进行深思熟虑的设计。随着我们不断创新并推动设计的边界，围绕凹弯曲的原则将始终在创造安全、功能性和美观的结构中发挥重要作用。