designed drag

简明释义

设计纵倾

英英释义

例句

1.Engineers focused on reducing designed drag when creating the prototype of the aircraft.

工程师在制作飞机原型时专注于减少设计阻力。

2.The new car model features a sleek design that minimizes designed drag for better fuel efficiency.

新款汽车模型采用流线型设计，减少了设计阻力，以提高燃油效率。

3.In the latest bike model, the designers aimed to achieve lower designed drag through aerodynamic improvements.

在最新的自行车模型中，设计师通过空气动力学改进来实现更低的设计阻力。

4.The athlete’s suit was crafted with designed drag in mind to enhance performance during competitions.

运动员的比赛服考虑到了设计阻力，以提高比赛表现。

5.The yacht's hull was optimized to reduce designed drag and enhance speed.

游艇的船体经过优化，以减少设计阻力并提高速度。

作文

In the world of engineering and design, the term designed drag refers to the intentional resistance that is created in a system to enhance performance or stability. This concept is particularly significant in fields such as aerodynamics, automotive design, and even in architectural engineering. Understanding how designed drag works can lead to innovative solutions in various industries. To illustrate the importance of designed drag, let’s consider the example of an airplane. When engineers design an aircraft, they must carefully balance the forces acting on it, including lift, weight, thrust, and drag. While drag is often viewed as a negative force that hinders performance, designed drag can actually be used strategically to improve the aircraft's stability during flight. By shaping the wings and fuselage in a specific way, engineers can create a form of drag that helps to keep the airplane steady, especially during turbulent conditions. Similarly, in automotive design, designed drag plays a crucial role in enhancing vehicle performance. Car manufacturers invest significant resources into wind tunnel testing to analyze how air flows around their vehicles. By understanding the effects of designed drag, engineers can modify the car's shape to minimize unwanted resistance while also creating downforce that improves traction and handling. This careful manipulation of aerodynamic principles allows for faster speeds and better control on the road. In architecture, designed drag can be seen in the design of buildings and structures that need to withstand strong winds or seismic activity. Architects may incorporate features that intentionally create drag, such as specific angles or materials, to ensure that the structure remains stable and safe under challenging environmental conditions. This foresight in design not only protects the integrity of the building but also enhances the safety of its occupants. Moreover, the concept of designed drag extends beyond physical structures and into the realm of technology and product design. For instance, in the development of consumer electronics, designers often consider how heat dissipation can be managed through designed drag. By creating airflow pathways that intentionally slow down the movement of air, devices can maintain optimal operating temperatures, thus prolonging their lifespan and improving performance. In conclusion, designed drag is a multifaceted concept that plays a vital role in various fields of engineering and design. By understanding and applying this principle, professionals can create more efficient, stable, and safe products and structures. Whether it’s in the air, on the road, or within our homes, the strategic use of designed drag showcases the ingenuity and creativity of engineers and designers who strive to push the boundaries of what is possible. As we continue to innovate and explore new frontiers, the importance of designed drag will undoubtedly remain a key consideration in the pursuit of excellence.

在工程和设计的世界中，术语designed drag指的是在系统中创造的有意阻力，以增强性能或稳定性。这个概念在空气动力学、汽车设计甚至建筑工程等领域尤为重要。理解designed drag的工作原理可以为各个行业带来创新解决方案。 为了说明designed drag的重要性，让我们考虑飞机的例子。当工程师设计一架飞机时，他们必须仔细平衡作用于飞机的力量，包括升力、重量、推力和阻力。虽然阻力通常被视为一种妨碍性能的负面力量，但designed drag实际上可以被战略性地使用以改善飞机在飞行中的稳定性。通过特定方式塑造机翼和机身，工程师可以创造出一种有助于保持飞机稳定的阻力，尤其是在动荡条件下。 同样，在汽车设计中，designed drag在提升车辆性能方面也起着至关重要的作用。汽车制造商在风洞测试中投入了大量资源，以分析空气如何流过他们的车辆。通过理解designed drag的影响，工程师可以修改汽车的形状，以最小化不必要的阻力，同时创造出改善牵引力和操控性的下压力。这种对空气动力学原理的精心操纵使得汽车能够以更快的速度行驶并在道路上获得更好的控制。 在建筑学中，designed drag可以在需要抵御强风或地震活动的建筑和结构设计中看到。建筑师可能会采用有意创造阻力的特征，例如特定的角度或材料，以确保结构在严峻环境条件下保持稳定和安全。这种设计上的前瞻性不仅保护了建筑的完整性，还增强了其居住者的安全性。 此外，designed drag的概念不仅限于物理结构，还延伸到技术和产品设计的领域。例如，在消费电子产品的开发中，设计师常常考虑如何通过designed drag管理热量散发。通过创建故意减缓空气流动的气流通道，设备可以维持最佳的工作温度，从而延长其使用寿命并提高性能。 总之，designed drag是一个多方面的概念，在各个工程和设计领域发挥着至关重要的作用。通过理解和应用这一原则，专业人士可以创造出更高效、更稳定和更安全的产品和结构。无论是在空中、在路上，还是在我们的家中，战略性地使用designed drag展示了工程师和设计师追求卓越的独创性和创造力。随着我们继续创新和探索新领域，designed drag的重要性无疑将始终是追求卓越的关键考量。