coefficient of weight efficiency
简明释义
重量利用系数
英英释义
例句
1.The coefficient of weight efficiency is crucial in automotive design to enhance performance and reduce emissions.
在汽车设计中,重量效率系数对于提升性能和减少排放至关重要。
2.The engineer calculated the coefficient of weight efficiency to determine how effectively the materials were used in the design.
工程师计算了重量效率系数以确定材料在设计中的使用效率。
3.In aerospace engineering, a higher coefficient of weight efficiency means a lighter aircraft with better fuel efficiency.
在航空航天工程中,较高的重量效率系数意味着飞机更轻,燃油效率更高。
4.By analyzing the coefficient of weight efficiency, the team was able to optimize the product's overall design.
通过分析重量效率系数,团队能够优化产品的整体设计。
5.To improve the coefficient of weight efficiency, we need to select lighter materials for the construction.
为了提高重量效率系数,我们需要为建筑选择更轻的材料。
作文
In the field of engineering and design, one crucial aspect that engineers must consider is the efficiency of materials used in various applications. Among the many factors that contribute to this efficiency, the coefficient of weight efficiency plays a significant role. This term refers to the ratio of the strength of a material to its weight, indicating how much load a material can bear relative to its mass. Understanding the coefficient of weight efficiency is essential for optimizing the performance of structures and components, especially in industries such as aerospace, automotive, and civil engineering.For instance, in aerospace engineering, where every gram counts, the coefficient of weight efficiency becomes a pivotal factor in material selection. Engineers strive to use materials that offer high strength while minimizing weight. This is because lighter materials can improve fuel efficiency and enhance the overall performance of aircraft. By calculating the coefficient of weight efficiency, engineers can compare different materials and choose the most suitable one for their designs. For example, aluminum and titanium are often preferred due to their favorable coefficient of weight efficiency, allowing for robust yet lightweight structures.Moreover, the coefficient of weight efficiency is not only relevant in aerospace but also in the automotive industry. As manufacturers aim to produce more fuel-efficient vehicles, understanding this coefficient helps in selecting the right materials for body frames, engines, and other components. A higher coefficient of weight efficiency means that the vehicle can maintain strength and safety while reducing overall weight, leading to better fuel economy and performance.In civil engineering, the coefficient of weight efficiency influences the choice of materials for infrastructure projects such as bridges and buildings. Engineers must ensure that the materials used can withstand various loads while remaining as lightweight as possible. This balance is crucial for the longevity and safety of structures. By analyzing the coefficient of weight efficiency of concrete, steel, and other materials, engineers can design more efficient and cost-effective solutions.In conclusion, the coefficient of weight efficiency is a fundamental concept that underpins many engineering decisions across various fields. By understanding and applying this coefficient, engineers can make informed choices that lead to innovative designs and improved performance in their projects. The ability to maximize strength while minimizing weight is not just a technical challenge; it is a pathway to achieving greater efficiency and sustainability in engineering practices. Ultimately, the coefficient of weight efficiency serves as a guiding principle for creating advanced materials and structures that meet the demands of modern technology and environmental considerations.
在工程和设计领域,工程师必须考虑的一个关键方面是所使用材料的效率。在众多影响效率的因素中,重量效率系数发挥着重要作用。这个术语指的是材料的强度与其重量的比率,表明材料相对于其质量可以承受多少负载。理解重量效率系数对于优化结构和组件的性能至关重要,尤其是在航空航天、汽车和土木工程等行业。例如,在航空航天工程中,每克都至关重要,重量效率系数成为材料选择的关键因素。工程师们努力使用既具有高强度又能最小化重量的材料。这是因为更轻的材料可以提高燃油效率并增强飞机的整体性能。通过计算重量效率系数,工程师可以比较不同材料,并选择最适合其设计的材料。例如,铝和钛通常因其有利的重量效率系数而受到青睐,从而允许构建坚固而轻便的结构。此外,重量效率系数不仅在航空航天中相关,在汽车工业中同样重要。随着制造商旨在生产更高燃油效率的车辆,理解这一系数有助于选择车身框架、发动机和其他组件的合适材料。更高的重量效率系数意味着车辆可以在保持强度和安全性的同时减少整体重量,从而提高燃油经济性和性能。在土木工程中,重量效率系数影响基础设施项目(如桥梁和建筑物)材料的选择。工程师必须确保所用材料能够承受各种负载,同时尽可能轻便。这种平衡对结构的耐久性和安全性至关重要。通过分析混凝土、钢材和其他材料的重量效率系数,工程师可以设计出更高效且具有成本效益的解决方案。总之,重量效率系数是支撑各个领域许多工程决策的基本概念。通过理解和应用这一系数,工程师可以做出明智的选择,从而在他们的项目中实现创新设计和改善性能。最大化强度的同时最小化重量不仅是技术挑战;它还是实现工程实践更高效率和可持续性的途径。最终,重量效率系数作为创造满足现代技术和环境要求的先进材料和结构的指导原则。
