forced-lubrication bearing

简明释义

强制润滑轴承

英英释义

例句

1.The engine operates more efficiently with a forced-lubrication bearing (强制润滑轴承) that ensures consistent oil flow.

该发动机通过使用强制润滑轴承（forced-lubrication bearing）以确保油流的持续性，从而提高了效率。

2.The design of the forced-lubrication bearing (强制润滑轴承) allows for better heat dissipation during operation.

该强制润滑轴承（forced-lubrication bearing）的设计允许在操作过程中更好地散热。

3.Maintenance teams often prefer forced-lubrication bearings (强制润滑轴承) due to their longer service life.

维护团队通常更喜欢使用强制润滑轴承（forced-lubrication bearings），因为它们的使用寿命更长。

4.In high-speed machinery, a forced-lubrication bearing (强制润滑轴承) is essential to reduce wear and tear.

在高速机械中，使用强制润滑轴承（forced-lubrication bearing）是减少磨损的重要因素。

5.A forced-lubrication bearing (强制润滑轴承) can be found in various applications, including automotive and aerospace industries.

在汽车和航空航天等多个应用中都能找到强制润滑轴承（forced-lubrication bearing）。

作文

In the realm of mechanical engineering, the efficiency and longevity of machinery heavily depend on the quality of its components. One such critical component is the bearing, which plays a vital role in reducing friction between moving parts. Among various types of bearings, the forced-lubrication bearing stands out due to its unique lubrication mechanism. The concept of forced-lubrication bearing refers to a system where lubricant is actively supplied to the bearing surfaces under pressure, ensuring a consistent and adequate flow of lubricant even under high load conditions. This is in contrast to conventional lubrication methods, which rely on gravity or capillary action to distribute the lubricant. The primary advantage of using a forced-lubrication bearing is its ability to minimize wear and tear on the bearing surfaces. The forced supply of lubricant creates a thin film that separates the moving parts, significantly reducing direct metal-to-metal contact. This not only prolongs the life of the bearing but also enhances the overall performance of the machinery. In applications where high speeds and loads are present, such as in turbines or heavy industrial equipment, the use of a forced-lubrication bearing can be crucial for maintaining operational efficiency. Moreover, the design of a forced-lubrication bearing system often includes features like pumps, filters, and reservoirs, which work together to ensure optimal lubrication. The integration of these components allows for precise control over the amount and temperature of the lubricant, further enhancing the bearing's performance. For instance, in high-temperature environments, a forced-lubrication bearing can help manage the heat generated by friction, thereby preventing overheating and potential failure of the bearing. In addition to industrial applications, forced-lubrication bearings are also utilized in automotive engines, where they play a key role in ensuring smooth operation. The engine's moving parts generate significant heat and friction, making effective lubrication essential. By employing a forced-lubrication bearing, manufacturers can improve engine efficiency and reduce the likelihood of breakdowns, ultimately leading to better performance and reliability. Furthermore, as technology advances, the development of smart lubrication systems has become increasingly popular. These systems can monitor the condition of the lubricant and the bearing in real time, adjusting the flow as necessary to maintain optimal performance. This innovation represents a significant step forward in the evolution of forced-lubrication bearings, allowing for even greater efficiency and longevity in machinery. In conclusion, the forced-lubrication bearing is an essential component in modern engineering, providing numerous benefits over traditional lubrication methods. Its ability to deliver consistent and effective lubrication under varying conditions makes it indispensable in high-performance applications. As industries continue to evolve, the importance of forced-lubrication bearings will only increase, highlighting the need for ongoing research and development in this critical area of mechanical engineering.

在机械工程领域，机器的效率和寿命在很大程度上取决于其组件的质量。其中一个关键组件是轴承，它在减少运动部件之间的摩擦方面发挥着重要作用。在各种类型的轴承中，强制润滑轴承因其独特的润滑机制而脱颖而出。强制润滑轴承的概念是指一种系统，其中润滑剂在压力下主动供应到轴承表面，确保在高负荷条件下也能保持一致和足够的润滑剂流动。这与依赖重力或毛细作用分配润滑剂的传统润滑方法形成对比。使用强制润滑轴承的主要优点是其能够最小化轴承表面的磨损。润滑剂的强制供应形成了一层薄膜，将运动部件分开，从而显著减少直接的金属接触。这不仅延长了轴承的使用寿命，还提高了机器的整体性能。在涡轮机或重型工业设备等高速和高负载的应用中，使用强制润滑轴承对于维持操作效率至关重要。此外，强制润滑轴承系统的设计通常包括泵、过滤器和储存装置，这些组件共同工作以确保最佳润滑。这些组件的集成使得能够精确控制润滑剂的量和温度，进一步增强了轴承的性能。例如，在高温环境中，强制润滑轴承可以帮助管理摩擦产生的热量，从而防止过热和潜在的轴承故障。除了工业应用，强制润滑轴承还广泛用于汽车发动机中，在确保平稳运行方面发挥着关键作用。发动机的运动部件产生显著的热量和摩擦，因此有效的润滑至关重要。通过采用强制润滑轴承，制造商可以提高发动机效率，减少故障的可能性，最终实现更好的性能和可靠性。此外，随着技术的进步，智能润滑系统的开发变得越来越流行。这些系统可以实时监测润滑剂和轴承的状态，根据需要调整流量，以保持最佳性能。这一创新代表了强制润滑轴承演变的重要一步，使机器的效率和耐用性进一步提升。总之，强制润滑轴承是现代工程中的一个重要组成部分，相较于传统润滑方法提供了许多好处。它在不同条件下提供一致和有效的润滑能力，使其在高性能应用中不可或缺。随着各行业的不断发展，强制润滑轴承的重要性只会增加，突显了在这一关键机械工程领域持续研究和发展的必要性。