rim of flywheel

简明释义

飞轮辋

英英释义

例句

1.During the performance test, we noticed vibrations coming from the rim of flywheel.

在性能测试中，我们注意到来自飞轮的边缘的振动。

2.To improve efficiency, the engineers decided to redesign the rim of flywheel.

为了提高效率，工程师们决定重新设计飞轮的边缘。

3.A crack in the rim of flywheel can lead to serious mechanical failures.

在飞轮的边缘上的裂缝可能会导致严重的机械故障。

4.The mechanic inspected the rim of flywheel for any signs of wear and tear.

机械师检查了飞轮的边缘是否有磨损的迹象。

5.The rim of flywheel must be balanced properly to ensure smooth operation.

为了确保平稳运行，飞轮的边缘必须正确平衡。

作文

In the realm of mechanical engineering, the term rim of flywheel refers to the outer edge of a flywheel, which is a crucial component in many machines. Flywheels are used to store rotational energy and help maintain a consistent speed in various mechanical systems. The rim of flywheel plays a significant role in determining the flywheel's moment of inertia, which directly affects how much energy it can store and how quickly it can respond to changes in speed. Understanding the importance of the rim of flywheel is essential for engineers and designers who work with kinetic energy systems.The primary function of a flywheel is to smooth out the fluctuations in energy supply and demand. For example, in an internal combustion engine, the flywheel absorbs energy during the power stroke and releases it during the exhaust stroke, ensuring a smoother operation. The rim of flywheel is designed to maximize the mass at the outer edge, where it can have the greatest leverage against the rotational axis. This design allows for greater energy storage capacity, making the flywheel more effective in its role.In addition to energy storage, the rim of flywheel also contributes to the stability of the system. A well-designed flywheel with an appropriately weighted rim of flywheel can reduce vibrations and enhance the overall performance of the machine. Engineers must carefully calculate the dimensions and materials used in the rim of flywheel to ensure that it can withstand the stresses imposed by high-speed rotation without failing.Moreover, the rim of flywheel can be made from various materials, including steel, aluminum, or composite materials, depending on the specific application. Each material has its advantages and disadvantages in terms of weight, strength, and cost. For instance, while a steel flywheel may offer durability, an aluminum flywheel may provide better performance due to its lighter weight. The choice of material for the rim of flywheel is often a trade-off between performance and cost-effectiveness.In modern applications, the concept of the rim of flywheel has evolved with advancements in technology. In electric vehicles, for example, flywheels are being explored as a means of energy storage to improve efficiency and reduce reliance on traditional batteries. These innovative designs utilize the principles of the rim of flywheel to create systems that can rapidly store and release energy, enhancing the vehicle's performance and range.In conclusion, the rim of flywheel is a vital component in various mechanical systems, serving not only as a means of energy storage but also as a stabilizing force within the machinery. Its design and material composition are critical factors that influence the efficiency and effectiveness of the flywheel. As technology continues to advance, understanding the role of the rim of flywheel will remain essential for engineers and designers working to create more efficient and reliable mechanical systems.

在机械工程领域，短语飞轮边缘指的是飞轮的外缘，这是许多机器中一个至关重要的组成部分。飞轮用于储存旋转能量，并帮助维持各种机械系统中的一致速度。飞轮边缘在决定飞轮的转动惯量方面发挥了重要作用，这直接影响到它能够储存多少能量以及它对速度变化的响应速度。理解飞轮边缘的重要性对从事动能系统工作的工程师和设计师至关重要。飞轮的主要功能是平滑能量供需波动。例如，在内燃机中，飞轮在动力冲程期间吸收能量，并在排气冲程期间释放能量，从而确保操作更加平稳。飞轮边缘的设计旨在最大化外缘的质量，因为它可以对旋转轴产生最大的杠杆作用。这种设计允许更大的能量储存能力，使飞轮在其角色中更有效。除了能量储存之外，飞轮边缘还对系统的稳定性做出了贡献。设计良好的飞轮，配有适当加重的飞轮边缘，可以减少振动并增强机器的整体性能。工程师必须仔细计算飞轮边缘的尺寸和材料，以确保它能够承受高速旋转所施加的压力而不发生故障。此外，飞轮边缘可以由多种材料制成，包括钢、铝或复合材料，具体取决于特定应用。每种材料在重量、强度和成本方面都有其优缺点。例如，虽然钢制飞轮可能提供耐用性，但铝制飞轮由于其较轻的重量可能提供更好的性能。对于飞轮边缘材料的选择通常是在性能和成本效益之间的权衡。在现代应用中，随着技术的进步，飞轮边缘的概念也在不断发展。例如，在电动车辆中，飞轮被探索作为一种能量储存方式，以提高效率并减少对传统电池的依赖。这些创新设计利用飞轮边缘的原理创建可以快速存储和释放能量的系统，从而增强车辆的性能和续航。总之，飞轮边缘是各种机械系统中的关键组成部分，不仅作为能量储存的手段，还作为机器内部的稳定力量。它的设计和材料组成是影响飞轮效率和效果的关键因素。随着技术的不断进步，理解飞轮边缘的作用将继续对工程师和设计师创造更高效、更可靠的机械系统至关重要。