compound load

简明释义

合成荷载

英英释义

例句

1.The compound load on the structure was assessed during the safety inspection.

在安全检查中评估了结构上的复合载荷。

2.The engineer calculated the compound load to ensure the bridge could support both vehicles and pedestrians.

工程师计算了复合载荷以确保桥梁能够支撑车辆和行人。

3.To prevent failure, the team monitored the compound load throughout the construction process.

为了防止失败，团队在整个施工过程中监测了复合载荷。

4.Understanding the compound load is crucial for ensuring the longevity of the materials used.

理解复合载荷对于确保所用材料的耐久性至关重要。

5.When designing the building, the architect considered the compound load from wind and snow.

在设计建筑时，建筑师考虑了来自风和雪的复合载荷。

作文

In the realm of engineering and physics, the term compound load refers to a situation where multiple forces or loads are applied to a structure simultaneously. Understanding how these loads interact is crucial for ensuring the safety and stability of various constructions, from bridges to buildings. The concept of compound load can be illustrated through several practical examples, demonstrating its significance in real-world applications.For instance, consider a bridge that is designed to support both vehicular traffic and pedestrian movement. The weight of cars, trucks, and buses constitutes a vertical load, while the presence of pedestrians adds an additional layer of complexity to the overall loading scenario. This combination of different types of loads acting on the bridge at the same time exemplifies a compound load. Engineers must carefully analyze these interactions to prevent structural failure and ensure that the bridge can withstand the various forces it encounters throughout its lifespan.Moreover, in the field of mechanical engineering, the concept of compound load becomes even more critical when dealing with machinery and equipment. For example, a crane lifting a heavy object not only experiences the weight of the load but also the dynamic forces generated by the movement of the crane itself. This scenario requires engineers to account for both static and dynamic loads, which together form a compound load that the crane must be designed to handle safely.Additionally, the implications of compound load extend beyond mere calculations; they also influence material selection and construction techniques. Materials must be chosen based on their ability to withstand the combined stresses imposed by the compound load. For instance, steel beams may be preferred for their strength and durability, while concrete may be used for its compressive strength in scenarios involving heavy vertical loads. The interplay between different materials and their response to compound load conditions is a fundamental consideration in structural design.Furthermore, the analysis of compound load is not limited to static structures. In the field of aerospace engineering, aircraft must be designed to endure various loads during flight, including lift, drag, and turbulence. Each of these factors contributes to a compound load that the aircraft's structure must accommodate. Engineers utilize advanced simulation tools to predict how these loads will affect the aircraft, ensuring that it remains stable and safe under all operating conditions.In conclusion, the term compound load encapsulates a complex interaction of forces that engineers must navigate in various fields. From civil engineering to aerospace, understanding and analyzing compound load is essential for designing safe and effective structures and systems. As technology advances, the methods for calculating and accommodating these loads continue to evolve, allowing for even greater innovations in engineering practices. Ultimately, a thorough grasp of compound load not only enhances the safety and reliability of structures but also paves the way for future advancements in engineering design and application.

在工程和物理学领域，术语复合载荷指的是多种力量或载荷同时施加在结构上的情况。理解这些载荷如何相互作用对于确保各种建筑物的安全性和稳定性至关重要，从桥梁到建筑物。复合载荷的概念可以通过几个实际例子来说明，展示其在现实应用中的重要性。例如，考虑一座设计用于支持车辆交通和行人流动的桥梁。汽车、卡车和公交车的重量构成了垂直载荷，而行人的存在则为整体载荷场景增加了一层复杂性。这种不同类型的载荷同时作用于桥梁的组合就是一个复合载荷。工程师必须仔细分析这些相互作用，以防止结构失效，并确保桥梁能够承受其整个生命周期中遇到的各种力量。此外，在机械工程领域，当涉及到机械和设备时，复合载荷的概念变得更加关键。例如，一台起重机在吊起重物时，不仅要承受负载的重量，还要承受起重机自身运动所产生的动态力量。这种情况要求工程师同时考虑静态和动态载荷，这两者共同形成了起重机必须安全处理的复合载荷。此外，复合载荷的影响不仅限于计算；它们还影响材料选择和施工技术。材料必须根据其承受复合载荷施加的组合应力的能力进行选择。例如，钢梁可能因其强度和耐久性而被优先使用，而混凝土可能因其在重垂直载荷下的抗压强度而被使用。不同材料之间的相互作用及其对复合载荷条件的反应是结构设计中的基本考虑因素。此外，复合载荷的分析不仅限于静态结构。在航空航天工程领域，飞机必须设计成能够承受飞行过程中产生的各种载荷，包括升力、阻力和湍流。这些因素每一个都对飞机的结构施加了复合载荷。工程师利用先进的仿真工具预测这些载荷将如何影响飞机，确保其在所有操作条件下保持稳定和安全。总之，术语复合载荷概括了工程师在各个领域必须应对的复杂力量相互作用。从土木工程到航空航天，理解和分析复合载荷对于设计安全有效的结构和系统至关重要。随着技术的进步，计算和适应这些载荷的方法也在不断发展，从而推动工程实践的更大创新。最终，深入理解复合载荷不仅增强了结构的安全性和可靠性，也为未来工程设计和应用的进步铺平了道路。