maneuverability coefficient
简明释义
操纵性系数
英英释义
例句
1.The racing team focused on increasing the maneuverability coefficient of their car to improve cornering speed.
赛车队专注于提高他们汽车的机动性系数以改善过弯速度。
2.The new drone model has a higher maneuverability coefficient which allows it to navigate through tight spaces more effectively.
新款无人机的机动性系数更高,使其能够更有效地穿越狭小空间。
3.A vehicle with a low maneuverability coefficient might struggle in urban environments with many obstacles.
一辆低机动性系数的车辆可能会在障碍物众多的城市环境中遇到困难。
4.Engineers are testing the maneuverability coefficient of the new submarine design to ensure it can handle underwater currents.
工程师们正在测试新潜艇设计的机动性系数,以确保其能够应对水下洋流。
5.In our latest simulation, we measured the maneuverability coefficient of various aircraft under different conditions.
在我们最新的模拟中,我们测量了不同条件下各种飞机的机动性系数。
作文
In the realm of engineering and design, particularly in the fields of aerospace and automotive industries, the term maneuverability coefficient is of paramount importance. This coefficient is a quantitative measure that indicates how easily a vehicle can change its direction or position in response to control inputs. Understanding this concept is crucial for engineers and designers who aim to create vehicles that are not only efficient but also highly responsive to the operator's commands.The maneuverability coefficient is influenced by several factors, including the vehicle's weight, shape, and the distribution of its mass. A vehicle with a high maneuverability coefficient can make sharp turns, accelerate quickly, and stop effectively, which is essential for safety and performance. For instance, in the design of fighter jets, engineers strive for a high maneuverability coefficient to ensure that the aircraft can perform complex aerial maneuvers during combat situations. This capability can mean the difference between success and failure in high-stakes scenarios.Moreover, the maneuverability coefficient is not just limited to military applications. In the automotive sector, sports cars are designed with a high maneuverability coefficient to enhance their performance on winding roads and racetracks. The ability to navigate sharp corners at high speeds is a critical factor that attracts enthusiasts to these vehicles. Engineers use advanced simulation tools to calculate and optimize the maneuverability coefficient during the design phase, ensuring that the final product meets the desired performance criteria.In addition to performance, the maneuverability coefficient also plays a significant role in safety. Vehicles with lower maneuverability may struggle to avoid obstacles or respond to sudden changes in traffic conditions, increasing the risk of accidents. Therefore, understanding and optimizing the maneuverability coefficient is essential not only for enhancing performance but also for ensuring the safety of drivers and passengers alike.Furthermore, as technology continues to evolve, the methods used to assess and improve the maneuverability coefficient have become more sophisticated. With the advent of computer-aided design (CAD) and computational fluid dynamics (CFD), engineers can simulate various scenarios and analyze how changes in design affect the maneuverability coefficient. This allows for more precise adjustments and innovations in vehicle design.In conclusion, the maneuverability coefficient is a critical parameter in the design and engineering of vehicles across various industries. Its implications extend beyond mere performance metrics; it encompasses aspects of safety, efficiency, and technological advancement. As we continue to push the boundaries of what is possible in vehicle design, understanding and optimizing the maneuverability coefficient will remain a key focus for engineers and designers alike. By prioritizing this coefficient, we can create vehicles that are not only powerful and fast but also agile and safe, ultimately enhancing the overall driving experience for users around the world.
在工程和设计领域,特别是在航空航天和汽车工业中,术语机动性系数至关重要。这个系数是一个定量指标,表明车辆在响应控制输入时改变其方向或位置的难易程度。理解这一概念对工程师和设计师来说至关重要,他们旨在创造不仅高效而且对操作员命令高度响应的车辆。机动性系数受多种因素影响,包括车辆的重量、形状和质量分布。具有高机动性系数的车辆可以快速转弯、迅速加速并有效制动,这对于安全和性能至关重要。例如,在战斗机的设计中,工程师努力实现高机动性系数,以确保飞机能够在战斗情况下执行复杂的空中机动。这种能力可能意味着在高风险场景中成功与失败之间的差别。此外,机动性系数不仅限于军事应用。在汽车行业,跑车的设计具有高机动性系数,以增强其在蜿蜒道路和赛道上的性能。在高速行驶中能够顺利通过急转弯是吸引爱好者选择这些车辆的关键因素。工程师使用先进的仿真工具在设计阶段计算和优化机动性系数,确保最终产品满足所需的性能标准。除了性能外,机动性系数在安全性方面也起着重要作用。机动性较低的车辆可能难以避开障碍物或应对交通条件的突然变化,从而增加事故风险。因此,理解和优化机动性系数不仅对提升性能至关重要,而且对确保驾驶员和乘客的安全也至关重要。此外,随着技术的不断发展,用于评估和改善机动性系数的方法变得更加复杂。随着计算机辅助设计(CAD)和计算流体动力学(CFD)的出现,工程师可以模拟各种场景,分析设计变化如何影响机动性系数。这使得更精确的调整和车辆设计创新成为可能。总之,机动性系数是各个行业车辆设计和工程中的关键参数。它的影响超越了简单的性能指标;它涵盖了安全性、效率和技术进步等方面。随着我们继续推动车辆设计的可能性界限,理解和优化机动性系数将始终是工程师和设计师关注的重点。通过优先考虑这一系数,我们可以创造出不仅强大和快速,而且灵活和安全的车辆,从而最终提升全球用户的整体驾驶体验。
