structural strength

简明释义

结构强度

英英释义

例句

1.The architect designed the building with an emphasis on structural strength to withstand earthquakes.

建筑师在设计建筑时强调结构强度，以抵御地震。

2.Testing the structural strength of a new material can help predict its performance in real-world applications.

测试新材料的结构强度可以帮助预测其在实际应用中的表现。

3.Materials with high structural strength are essential for building skyscrapers.

具有高结构强度的材料对于建造摩天大楼至关重要。

4.The structural strength of the dam was evaluated to ensure it could hold back the water during heavy rains.

对大坝的结构强度进行了评估，以确保它能够在大雨期间挡住水流。

5.The engineer conducted tests to determine the structural strength of the bridge before opening it to traffic.

工程师进行测试以确定桥梁的结构强度，以便在开放交通之前。

作文

The concept of structural strength refers to the ability of a structure to withstand its intended load without experiencing failure. This principle is crucial in various fields, including civil engineering, architecture, and manufacturing. Understanding structural strength helps engineers design buildings, bridges, and other infrastructures that can endure environmental forces such as wind, earthquakes, and heavy traffic. To illustrate, consider the design of a skyscraper. Engineers must calculate the structural strength of materials like steel and concrete to ensure that the building can support its own weight, as well as additional loads from occupants, furniture, and equipment. If the structural strength is inadequate, the building risks collapsing or sustaining severe damage. Therefore, rigorous testing and analysis are conducted during the design phase to guarantee safety and durability.Moreover, structural strength is not only about the materials used but also about how those materials are arranged and connected. For instance, the shape of a beam can significantly affect its structural strength. A triangular truss is often stronger than a rectangular one due to the distribution of forces throughout the structure. By optimizing these designs, engineers can create more efficient structures that use fewer materials while maintaining safety standards.In addition to traditional construction, the concept of structural strength is increasingly relevant in modern technologies, such as aerospace engineering and automotive design. Aircraft and vehicles must be lightweight for efficiency but also possess sufficient structural strength to withstand the stresses of flight or driving. Innovations in materials science, such as carbon fiber and advanced alloys, have allowed engineers to enhance structural strength while reducing weight, leading to better performance and fuel efficiency.Furthermore, the importance of structural strength extends to sustainability. As society becomes more aware of environmental issues, there is a growing emphasis on constructing buildings and infrastructures that are not only strong but also sustainable. This means using recycled materials, minimizing waste, and designing structures that can adapt to changing conditions. By focusing on structural strength in sustainable design, we can create resilient buildings that last longer and require less maintenance over time.In conclusion, structural strength is a fundamental aspect of engineering and design that ensures the safety and longevity of structures. Its significance spans across various industries, influencing everything from skyscrapers to airplanes. As technology advances and the demand for sustainable solutions increases, the understanding and application of structural strength will continue to evolve. Engineers and architects must remain vigilant in their pursuit of innovative designs that prioritize structural strength while addressing the pressing challenges of our time.

“结构强度”这一概念指的是结构在不发生故障的情况下承受其预期载荷的能力。这个原理在土木工程、建筑和制造等多个领域至关重要。理解“结构强度”有助于工程师设计能够承受风、地震和重型交通等环境力量的建筑、桥梁和其他基础设施。以摩天大楼的设计为例。工程师必须计算像钢材和混凝土这样的材料的“结构强度”，以确保建筑能够支持自身的重量，以及来自居民、家具和设备的额外负荷。如果“结构强度”不足，建筑物就有倒塌或遭受严重损坏的风险。因此，在设计阶段进行严格的测试和分析，以确保安全性和耐久性是必不可少的。此外，“结构强度”不仅与所使用的材料有关，还与这些材料的排列和连接方式有关。例如，梁的形状可以显著影响其“结构强度”。三角桁架通常比矩形桁架更强，因为力在整个结构中的分布不同。通过优化这些设计，工程师可以创建更高效的结构，使用更少的材料，同时保持安全标准。除了传统建筑外，“结构强度”的概念在现代技术中也越来越相关，例如航空航天工程和汽车设计。飞机和车辆必须轻便以提高效率，但也必须具备足够的“结构强度”以承受飞行或驾驶的压力。材料科学的创新，例如碳纤维和先进合金，使工程师能够在减轻重量的同时增强“结构强度”，从而提高性能和燃油效率。此外，“结构强度”的重要性还延伸至可持续性。随着社会对环境问题的认识日益增强，建设不仅强大而且可持续的建筑和基础设施的重视程度不断上升。这意味着使用回收材料、最小化废物以及设计可以适应变化条件的结构。通过关注可持续设计中的“结构强度”，我们可以创造出更具韧性的建筑，这些建筑能够更长久地使用并在时间上需要更少的维护。总之，“结构强度”是工程和设计的一个基本方面，确保结构的安全性和耐久性。它的重要性跨越多个行业，影响着摩天大楼到飞机的方方面面。随着科技的进步和对可持续解决方案的需求增加，对“结构强度”的理解和应用将继续发展。工程师和建筑师必须在追求创新设计的过程中保持警觉，优先考虑“结构强度”，同时应对我们时代的紧迫挑战。