steady-turning radius

简明释义

稳定旋回半径

英英释义

例句

1.The design of the racetrack incorporates curves that require a precise steady-turning radius 稳定转弯半径 for optimal speed.

赛道的设计包含需要精确的steady-turning radius 稳定转弯半径以实现最佳速度的曲线。

2.The vehicle's performance was tested at various speeds to determine its steady-turning radius 稳定转弯半径.

车辆在不同速度下进行性能测试，以确定其steady-turning radius 稳定转弯半径。

3.In aviation, the steady-turning radius 稳定转弯半径 is crucial for calculating safe flight paths during maneuvers.

在航空领域，steady-turning radius 稳定转弯半径对于计算飞行操作中的安全飞行路径至关重要。

4.During the driving test, the instructor emphasized the importance of maintaining a consistent steady-turning radius 稳定转弯半径.

在驾驶测试中，教练强调了保持一致的steady-turning radius 稳定转弯半径的重要性。

5.A smaller steady-turning radius 稳定转弯半径 allows for better maneuverability in tight spaces.

较小的steady-turning radius 稳定转弯半径可以在狭小空间内提供更好的机动性。

作文

In the realm of engineering and vehicle dynamics, the concept of a steady-turning radius is crucial for understanding how vehicles navigate through curves and turns. The steady-turning radius refers to the constant distance from the center of a circular path to the outer edge of the vehicle when it is moving in a steady state around that path. This parameter is essential for designing safe and efficient vehicles, especially in applications involving high-speed travel, such as racing cars, airplanes, and even public transportation systems.To illustrate the importance of the steady-turning radius, consider a scenario where a car is approaching a sharp bend in the road. The driver must assess the vehicle's speed and the curvature of the road to determine whether it can safely navigate the turn without losing control. If the steady-turning radius of the vehicle is too large relative to the turn's radius, the car may skid or roll over, leading to dangerous situations. Therefore, engineers must carefully calculate this radius to ensure that vehicles can handle various driving conditions.The steady-turning radius also plays a significant role in the design of roads and highways. Urban planners and civil engineers take this measurement into account when designing curves on roads to ensure that vehicles can navigate them safely at typical speeds. Roads with sharp turns require a larger steady-turning radius to accommodate larger vehicles, such as trucks and buses, which have different handling characteristics compared to smaller cars. By incorporating the appropriate steady-turning radius into road design, traffic flow can be improved, and accidents can be minimized.In addition to vehicles and road design, the steady-turning radius is also relevant in the field of aviation. Aircraft must adhere to specific turning radii during flight maneuvers to maintain stability and control. Pilots are trained to understand how their aircraft responds to different turning radii, which is critical for safe navigation, especially during takeoff and landing phases. The steady-turning radius in aviation ensures that pilots can execute turns without exceeding the aircraft's performance limits.Moreover, the steady-turning radius is not only about safety but also about efficiency. Vehicles with a smaller steady-turning radius can maneuver more easily in tight spaces, making them ideal for urban environments where space is limited. For instance, compact cars often feature a smaller steady-turning radius, allowing drivers to navigate narrow streets and parking lots with ease. On the other hand, larger vehicles, such as SUVs and trucks, typically have a larger steady-turning radius, which can make them less maneuverable in confined areas.In conclusion, the concept of steady-turning radius is a fundamental aspect of vehicle dynamics that influences safety, design, and efficiency across various modes of transportation. Understanding this term allows engineers, planners, and drivers to make informed decisions regarding vehicle operation and infrastructure development. As technology advances, the implications of steady-turning radius will continue to evolve, ensuring that transportation remains safe and efficient for everyone involved.

在工程和车辆动力学领域，稳定转弯半径的概念对于理解车辆如何通过曲线和转弯至关重要。稳定转弯半径是指在车辆以稳定状态沿着圆形路径移动时，从圆心到车辆外缘的恒定距离。这个参数对于设计安全高效的车辆至关重要，尤其是在涉及高速行驶的应用中，例如赛车、飞机，甚至公共交通系统。为了说明稳定转弯半径的重要性，考虑一个场景：一辆车正在接近道路上的急转弯。司机必须评估车辆的速度和道路的曲率，以确定它是否可以安全地通过转弯而不失去控制。如果车辆的稳定转弯半径相对于转弯的半径过大，汽车可能会打滑或翻倒，导致危险情况。因此，工程师必须仔细计算这个半径，以确保车辆能够应对各种驾驶条件。稳定转弯半径在道路和高速公路的设计中也起着重要作用。城市规划者和土木工程师在设计道路的曲线时会考虑这个测量，以确保车辆能够安全地以典型速度通过它们。具有急转弯的道路需要更大的稳定转弯半径，以适应较大的车辆，如卡车和公交车，这些车辆与小型汽车相比具有不同的操控特性。通过将适当的稳定转弯半径纳入道路设计，可以改善交通流量并减少事故。除了车辆和道路设计，稳定转弯半径在航空领域也很相关。飞机在飞行机动中必须遵循特定的转弯半径，以保持稳定性和控制力。飞行员接受培训，以了解他们的飞机如何响应不同的转弯半径，这对于安全导航至关重要，尤其是在起飞和着陆阶段。航空中的稳定转弯半径确保飞行员可以执行转弯而不超过飞机的性能限制。此外，稳定转弯半径不仅关乎安全，也关乎效率。具有较小稳定转弯半径的车辆可以更轻松地在狭小空间内机动，使其非常适合空间有限的城市环境。例如，紧凑型汽车通常具有较小的稳定转弯半径，允许司机轻松穿越狭窄的街道和停车场。另一方面，较大的车辆，如SUV和卡车，通常具有较大的稳定转弯半径，这可能使它们在封闭区域内的机动性降低。总之，稳定转弯半径的概念是车辆动力学的基本方面，影响着各类交通工具的安全、设计和效率。理解这个术语使工程师、规划者和司机能够就车辆操作和基础设施发展做出明智的决策。随着技术的进步，稳定转弯半径的含义将继续演变，确保交通对所有参与者都保持安全和高效。