traction resistance

简明释义

牵引阻力

英英释义

例句

1.A higher traction resistance 牵引阻力 can lead to better grip on slippery surfaces.

更高的牵引阻力可以在滑溜的表面上提供更好的抓地力。

2.The car struggled to move forward due to the high traction resistance 牵引阻力 from the muddy terrain.

由于泥泞地形的高牵引阻力，汽车难以向前移动。

3.Engineers must consider traction resistance 牵引阻力 when designing vehicles for off-road conditions.

工程师在为越野条件设计车辆时必须考虑牵引阻力。

4.The team conducted tests to measure the traction resistance 牵引阻力 of different materials.

团队进行了测试，以测量不同材料的牵引阻力。

5.The traction resistance 牵引阻力 of the tires increased significantly on wet roads.

在湿滑路面上，轮胎的牵引阻力显著增加。

作文

In the world of physics and engineering, the concept of traction resistance plays a crucial role in understanding how forces interact with surfaces. Traction resistance refers to the frictional force that opposes the motion of an object when it is in contact with another surface. This resistance is significant in various applications, including vehicles, machinery, and even sports equipment. Understanding how traction resistance works can greatly enhance performance and efficiency in these areas.For instance, consider a car driving on a highway. The tires of the car create a contact patch with the road, and it is this area where traction resistance comes into play. When the driver accelerates, the engine generates power that is transmitted to the wheels. The tires push against the road, and due to traction resistance, the car moves forward. However, if the road is wet or covered in ice, the traction resistance decreases, making it harder for the tires to grip the surface. This reduction in traction resistance can lead to skidding or loss of control, highlighting the importance of understanding this concept in automotive design and safety.Moreover, in sports, athletes must also contend with traction resistance to optimize their performance. For example, a sprinter relies on the grip of their spikes against the track surface to propel themselves forward. If the traction resistance is too low, the athlete may slip, resulting in a poor start or even injury. Conversely, if the traction resistance is too high, it may hinder their ability to move quickly. Therefore, selecting the right footwear that offers the ideal balance of traction resistance is essential for success in competitive sports.In the field of machinery, traction resistance is equally important. Heavy machinery, such as bulldozers and excavators, must overcome traction resistance to move effectively across various terrains. Engineers must carefully calculate the required force to ensure that these machines can operate efficiently without getting stuck in mud or sand. By understanding the dynamics of traction resistance, engineers can design better tires and tracks that enhance mobility and productivity on job sites.The study of traction resistance also extends to the realm of robotics. Robots designed for specific tasks must navigate different surfaces, and their ability to do so often depends on how well they manage traction resistance. For instance, a robot intended for search-and-rescue missions may need to traverse rubble or uneven ground. Understanding the principles of traction resistance allows engineers to develop robots that can maintain stability and mobility in challenging environments.In conclusion, traction resistance is a fundamental concept that influences many aspects of our daily lives, from driving cars to competing in sports and operating machinery. By gaining a deeper understanding of traction resistance, we can improve designs, enhance safety, and optimize performance across various fields. Whether it’s ensuring that a vehicle can stop safely or helping an athlete achieve their personal best, the implications of traction resistance are far-reaching and essential for progress in technology and human activity.

在物理和工程领域中，概念牵引阻力在理解力与表面之间的相互作用方面起着至关重要的作用。牵引阻力是指当物体与另一表面接触时，反对其运动的摩擦力。这种阻力在各种应用中都很重要，包括车辆、机械以及甚至体育器材。理解牵引阻力的工作原理可以大大提高这些领域的性能和效率。例如，考虑一辆在高速公路上行驶的汽车。汽车的轮胎与路面形成接触区，而正是在这个区域中，牵引阻力发挥了作用。当司机加速时，发动机产生的动力被传递到车轮。轮胎向路面施加压力，由于牵引阻力的存在，汽车向前移动。然而，如果路面湿滑或覆盖着冰，牵引阻力会减小，导致轮胎难以抓住表面。这种牵引阻力的降低可能会导致打滑或失去控制，突显了在汽车设计和安全中理解这一概念的重要性。此外，在体育运动中，运动员也必须应对牵引阻力以优化他们的表现。例如，短跑运动员依赖他们的钉鞋在跑道表面上的抓地力来推动自己向前。如果牵引阻力过低，运动员可能会滑倒，导致起跑不良甚至受伤。相反，如果牵引阻力过高，可能会妨碍他们快速移动。因此，选择提供理想牵引阻力平衡的合适鞋类对于竞技体育的成功至关重要。在机械领域，牵引阻力同样重要。重型机械，如推土机和挖掘机，必须克服牵引阻力才能有效地在各种地形上移动。工程师必须仔细计算所需的力量，以确保这些机器能够高效运作，而不会陷入泥浆或沙子中。通过理解牵引阻力的动态，工程师可以设计出更好的轮胎和履带，从而增强工地的机动性和生产力。牵引阻力的研究还扩展到机器人领域。为特定任务设计的机器人必须在不同的表面上导航，它们的能力往往取决于它们如何管理牵引阻力。例如，旨在进行搜索和救援任务的机器人可能需要穿越瓦砾或不平坦的地面。理解牵引阻力的原理使工程师能够开发出能够在具有挑战性的环境中保持稳定性和机动性的机器人。总之，牵引阻力是一个基本概念，影响着我们日常生活的许多方面，从驾驶汽车到参加体育比赛，再到操作机械。通过深入理解牵引阻力，我们可以改善设计，增强安全性，并优化各个领域的性能。无论是确保车辆安全停车，还是帮助运动员实现个人最佳，牵引阻力的影响都是深远的，对于技术和人类活动的进步至关重要。