yield to weight ratio

简明释义

比威力

英英释义

例句

1.In the automotive industry, a high yield to weight ratio 抗拉强度与重量比 is crucial for improving fuel efficiency and performance.

在汽车工业中，高yield to weight ratio 抗拉强度与重量比对提高燃油效率和性能至关重要。

2.Researchers found that the yield to weight ratio 抗拉强度与重量比 of composite materials can significantly outperform traditional metals.

研究人员发现，复合材料的yield to weight ratio 抗拉强度与重量比可以显著超过传统金属。

3.The aerospace engineers calculated the yield to weight ratio 抗拉强度与重量比 of the new aircraft design to ensure it meets safety standards.

航空工程师计算了新飞机设计的yield to weight ratio 抗拉强度与重量比，以确保其符合安全标准。

4.The construction team evaluated the yield to weight ratio 抗拉强度与重量比 of different steel types before making their final decision.

施工团队在做出最终决定之前评估了不同钢材的yield to weight ratio 抗拉强度与重量比。

5.When selecting materials for the bridge, the team focused on the yield to weight ratio 抗拉强度与重量比 to enhance durability without adding excess weight.

在选择桥梁材料时，团队专注于yield to weight ratio 抗拉强度与重量比，以提高耐久性而不增加额外重量。

作文

The concept of yield to weight ratio is crucial in various fields, particularly in engineering and materials science. This ratio refers to the amount of stress a material can withstand before it begins to deform, relative to its weight. Understanding this ratio helps engineers and designers select the appropriate materials for specific applications, ensuring safety and efficiency in structures and products.For instance, in the aerospace industry, where weight is a critical factor, materials with a high yield to weight ratio are preferred. These materials can endure significant stress while remaining lightweight, which is essential for aircraft performance and fuel efficiency. If an aircraft is built using materials that do not have a favorable yield to weight ratio, it could lead to excessive weight, resulting in increased fuel consumption and reduced payload capacity.Similarly, in the automotive industry, the yield to weight ratio plays a vital role in vehicle design. Engineers strive to create vehicles that are both strong and lightweight. By selecting materials with a high yield to weight ratio, they can enhance the vehicle's performance, improve fuel efficiency, and ensure safety without compromising on structural integrity. For example, advanced composites and high-strength steel are often used in modern vehicles for this very reason.Moreover, the yield to weight ratio is not only applicable to large-scale engineering projects but also to everyday items such as sports equipment. Take bicycles, for instance. Manufacturers aim to produce bikes that are lightweight yet durable. A bike with a high yield to weight ratio will allow riders to accelerate quickly and maneuver easily, providing a better overall riding experience.In construction, the yield to weight ratio influences the choice of materials for buildings and bridges. A structure built with materials that have a low yield to weight ratio may face challenges such as sagging or even failure under heavy loads. Therefore, architects and civil engineers must carefully consider this ratio when designing safe and robust structures.In conclusion, the yield to weight ratio is a fundamental concept that impacts various industries by guiding material selection and design processes. By prioritizing materials with a high yield to weight ratio, professionals can create safer, more efficient, and more effective products and structures. As technology advances, the development of new materials with improved yield to weight ratios will continue to revolutionize engineering practices and enhance performance across multiple domains.

“抗拉强度与重量比”的概念在多个领域中至关重要，尤其是在工程和材料科学中。这个比率指的是材料在开始变形之前能够承受的应力量，相对于其重量。理解这个比率有助于工程师和设计师选择适合特定应用的材料，从而确保结构和产品的安全性和效率。例如，在航空航天工业中，重量是一个关键因素，因此更倾向于使用具有高“抗拉强度与重量比”的材料。这些材料能够承受显著的应力，同时保持轻便，这对飞机的性能和燃油效率至关重要。如果使用不具备良好“抗拉强度与重量比”的材料建造飞机，可能会导致过重，从而增加燃料消耗并降低载货能力。同样，在汽车工业中，“抗拉强度与重量比”在车辆设计中也扮演着重要角色。工程师努力创造既坚固又轻便的车辆。通过选择具有高“抗拉强度与重量比”的材料，他们可以提高车辆的性能，改善燃油效率，并确保安全，而不会妥协结构的完整性。例如，现代车辆常常使用先进的复合材料和高强度钢正是出于这个原因。此外，“抗拉强度与重量比”不仅适用于大型工程项目，也适用于日常物品，如运动器材。以自行车为例。制造商旨在生产轻便而耐用的自行车。具有高“抗拉强度与重量比”的自行车将使骑行者能够快速加速并轻松操控，从而提供更好的整体骑行体验。在建筑方面，“抗拉强度与重量比”影响着建筑物和桥梁的材料选择。使用低“抗拉强度与重量比”的材料建造的结构可能面临如下垂或甚至在重负荷下失效等挑战。因此，建筑师和土木工程师在设计安全且坚固的结构时必须仔细考虑这一比率。总之，“抗拉强度与重量比”是一个基本概念，它通过指导材料选择和设计过程影响多个行业。通过优先选择具有高“抗拉强度与重量比”的材料，专业人士可以创造出更安全、更高效和更有效的产品和结构。随着技术的进步，开发出具有更好“抗拉强度与重量比”的新材料将继续革新工程实践，并提升多个领域的性能。