compressive force

简明释义

压缩力

英英释义

例句

1.A rock's ability to resist compressive forces 压缩力 is crucial for its stability in geological formations.

岩石抵抗压缩力的能力对于其在地质构造中的稳定性至关重要。

2.The engineering team calculated the maximum compressive force 压缩力 that the beam could handle.

工程团队计算了梁可以承受的最大压缩力。

3.The bridge was designed to withstand significant compressive force 压缩力 from the weight of vehicles.

这座桥梁的设计能够承受来自车辆重量的显著压缩力。

4.In construction, columns bear compressive forces 压缩力 that help support the structure above.

在建筑中，柱子承受着帮助支撑上方结构的压缩力。

5.When a material is squeezed, it experiences compressive force 压缩力, which can lead to deformation.

当材料被挤压时，它会经历压缩力，这可能导致变形。

作文

In the field of engineering and physics, understanding the concept of compressive force is crucial for designing structures that can withstand various loads. A compressive force is defined as a force that acts to compress or shorten an object. This type of force is fundamental in many applications, from the construction of buildings to the manufacturing of materials. When we think about the weight of a building resting on its foundation, we can visualize how the walls and columns experience compressive forces due to the weight above them.When a structure is subjected to a load, the materials within that structure respond to the compressive forces by deforming. For example, concrete is a material that performs exceptionally well under compression. It can bear significant loads without failing, which is why it is commonly used in the foundations and supports of buildings. However, every material has its limits. If the compressive force exceeds the material's capacity, it can lead to failure, resulting in cracks or even catastrophic collapse.The study of compressive forces also extends to various engineering disciplines, including civil, mechanical, and aerospace engineering. In civil engineering, understanding how compressive forces affect the design of bridges and towers is essential. Engineers must calculate the maximum load that a structure can bear and ensure that the materials used can handle those forces safely.In mechanical engineering, components like beams and columns are designed with compressive forces in mind. For instance, when designing a bridge, engineers must consider not only the weight of the vehicles that will cross it but also the compressive forces exerted by the bridge's own weight and environmental factors such as wind and earthquakes.Aerospace engineering also involves compressive forces. Aircraft wings, for example, experience different types of forces during flight, including compressive forces during takeoff and landing. Engineers must ensure that these components can withstand the compressive forces encountered during operation without compromising safety.Moreover, the impact of compressive forces is not limited to large structures. Everyday objects, such as furniture, are also designed considering these forces. For instance, a table must be able to support the weight of items placed on it without collapsing. The legs of the table experience compressive forces as they support the tabletop and any additional weight.In conclusion, compressive force is a fundamental concept in various fields of study and practical applications. Whether in large-scale constructions like skyscrapers and bridges or everyday items like furniture, understanding how compressive forces work allows engineers and designers to create safe and functional products. As technology advances, the analysis and application of compressive forces continue to evolve, leading to innovative designs that enhance safety and efficiency in our built environment.

在工程和物理学领域，理解压缩力的概念对于设计能够承受各种负载的结构至关重要。压缩力被定义为一种作用于物体以压缩或缩短其长度的力量。这种类型的力量在许多应用中是基础，从建筑物的建造到材料的制造。当我们想到一座建筑的重量压在其基础上时，可以想象墙壁和柱子由于上方的重量而经历压缩力。当结构受到负载时，结构内的材料对压缩力作出反应，发生变形。例如，混凝土是一种在压缩下表现非常好的材料。它可以承受显著的负载而不失效，这就是为什么它常用于建筑物的基础和支撑。然而，每种材料都有其极限。如果压缩力超过材料的承载能力，就会导致失效，造成裂缝甚至灾难性的倒塌。对压缩力的研究还扩展到多个工程学科，包括土木工程、机械工程和航空航天工程。在土木工程中，理解压缩力如何影响桥梁和塔楼的设计至关重要。工程师必须计算出结构能够承受的最大负载，并确保所用材料能够安全地处理这些力量。在机械工程中，像梁和柱这样的部件的设计考虑了压缩力。例如，在设计桥梁时，工程师不仅必须考虑将要通过的车辆的重量，还要考虑桥梁自身的重量以及风和地震等环境因素所施加的压缩力。航空航天工程也涉及压缩力。飞机机翼在飞行过程中会经历不同类型的力量，包括在起飞和着陆时的压缩力。工程师必须确保这些部件能够承受在操作过程中遇到的压缩力，而不妨碍安全。此外，压缩力的影响并不限于大型结构。日常物品，如家具，也是在考虑这些力量的情况下设计的。例如，一张桌子必须能够支持放在其上的物品的重量，而不会崩溃。桌子的腿在支持桌面和任何额外重量时经历压缩力。总之，压缩力是各个研究领域和实际应用中的基本概念。无论是在摩天大楼和桥梁等大规模建筑中，还是在家具等日常物品中，理解压缩力的工作原理使工程师和设计师能够创建安全且功能良好的产品。随着技术的进步，对压缩力的分析和应用不断发展，推动了创新设计的出现，从而提高了我们建筑环境中的安全性和效率。