divided bearing
简明释义
对开轴承
英英释义
A divided bearing is a type of bearing that is split into two or more parts to facilitate easier installation, maintenance, or replacement. | 分体轴承是一种将轴承分为两个或多个部分的类型,以便于更简单的安装、维护或更换。 |
例句
1.The engineer explained how the divided bearing 分隔轴承 helps reduce friction in rotating machinery.
工程师解释了如何使用divided bearing 分隔轴承来减少旋转机械中的摩擦。
2.In high-speed applications, a divided bearing 分隔轴承 can significantly improve performance.
在高速应用中,divided bearing 分隔轴承可以显著提高性能。
3.The divided bearing 分隔轴承 design allows for better load distribution across the shaft.
这种divided bearing 分隔轴承设计允许更好的负载分配到轴上。
4.During the assembly, the technician installed the divided bearing 分隔轴承 carefully to ensure proper alignment.
在组装过程中,技术员小心地安装了divided bearing 分隔轴承以确保正确对齐。
5.Manufacturers often choose a divided bearing 分隔轴承 for its ease of maintenance.
制造商通常选择divided bearing 分隔轴承因为它便于维护。
作文
In the world of engineering and mechanics, the term divided bearing refers to a specific type of support used to reduce friction between moving parts. This concept is crucial in various applications, from simple machines to complex automotive systems. Understanding divided bearing can enhance our appreciation of how modern machinery operates efficiently and reliably.A divided bearing typically consists of two or more segments that work together to distribute load evenly across a surface. This design allows for greater flexibility and adaptability in mechanical systems. For instance, in a rotating shaft, a divided bearing can accommodate misalignment or thermal expansion, which are common issues in mechanical assemblies. By having multiple segments, the bearing can adjust to changing conditions without compromising performance.One of the key advantages of using a divided bearing is its ability to reduce wear and tear on components. As machinery operates, friction is generated, which can lead to overheating and eventual failure if not properly managed. The segmented nature of a divided bearing allows for better lubrication distribution, ensuring that all parts receive adequate oil or grease. This not only prolongs the lifespan of the bearing itself but also protects adjacent components from damage caused by excessive friction.Moreover, divided bearings are often easier to maintain than traditional solid bearings. In many cases, individual segments can be replaced or serviced without needing to dismantle the entire assembly. This can save time and reduce costs in maintenance operations. For example, in large industrial machines, where downtime can be costly, the ability to quickly address bearing issues can significantly enhance productivity.The design of a divided bearing can vary widely depending on the application. Some are designed for high-speed operations, while others are built to handle heavy loads. Engineers must consider factors such as material selection, lubrication methods, and environmental conditions when designing a divided bearing. Advanced materials, such as polymers and composites, are often used to create lightweight yet durable segments that can withstand harsh operating conditions.In addition to their mechanical benefits, divided bearings play a role in energy efficiency. By minimizing friction and wear, these bearings help reduce the amount of energy required to operate machinery. This is particularly important in today’s world, where energy conservation and sustainability are paramount. Industries are continuously seeking ways to improve efficiency and reduce their environmental impact, and the use of divided bearings is one strategy that can contribute to these goals.In conclusion, the concept of divided bearing is essential for anyone involved in engineering or mechanical design. Its ability to distribute loads, reduce friction, and simplify maintenance makes it a valuable component in many systems. As technology advances, the design and application of divided bearings will continue to evolve, offering new solutions to the challenges faced by modern machinery. Understanding this term not only enriches our knowledge of mechanical systems but also highlights the importance of innovation in engineering practices. Overall, the significance of divided bearing extends beyond mere functionality; it represents a commitment to improving performance and reliability in various fields of engineering. By embracing these advancements, we can look forward to a future where machinery operates more efficiently and sustainably than ever before.
在工程和机械领域,术语分体轴承指的是一种用于减少运动部件之间摩擦的特定支撑类型。这个概念在从简单机器到复杂汽车系统的各种应用中都至关重要。理解分体轴承可以增强我们对现代机械高效可靠运行的欣赏。分体轴承通常由两个或多个部分组成,这些部分共同作用以在表面上均匀分配负载。这种设计允许机械系统具有更大的灵活性和适应性。例如,在旋转轴中,分体轴承可以适应不对中或热膨胀,这是机械组件中常见的问题。通过多个部分的设计,轴承可以在不妨碍性能的情况下适应变化的条件。使用分体轴承的一个主要优点是它能够减少部件的磨损。在机械运作过程中,会产生摩擦,这可能导致过热和最终故障,如果没有得到妥善管理。分体轴承的分段特性允许更好的润滑分布,确保所有部件都能获得足够的油或脂。这不仅延长了轴承本身的使用寿命,还保护了邻近组件免受过度摩擦造成的损害。此外,分体轴承通常比传统的实心轴承更易于维护。在许多情况下,单个部分可以在不需要拆卸整个组件的情况下更换或服务。这可以节省维护操作中的时间和成本。例如,在大型工业机器中,停机时间可能会很昂贵,快速解决轴承问题的能力可以显著提高生产力。分体轴承的设计可以根据应用的不同而变化。有些设计用于高速操作,而另一些则旨在处理重负荷。工程师在设计分体轴承时必须考虑材料选择、润滑方法和环境条件等因素。先进的材料,如聚合物和复合材料,通常用于制造轻质但耐用的部分,这些部分能够承受恶劣的操作条件。除了机械优势外,分体轴承在能源效率方面也发挥着作用。通过最小化摩擦和磨损,这些轴承有助于减少操作机械所需的能量。这在今天的世界中尤其重要,因为节能和可持续性至关重要。各行业不断寻求提高效率和减少环境影响的方法,而使用分体轴承就是实现这些目标的一种策略。总之,分体轴承的概念对于任何参与工程或机械设计的人来说都是至关重要的。它在负载分配、减少摩擦和简化维护方面的能力使其成为许多系统中的重要组成部分。随着技术的进步,分体轴承的设计和应用将继续发展,为现代机械面临的挑战提供新的解决方案。理解这个术语不仅丰富了我们对机械系统的知识,也突显了工程实践中创新的重要性。总体而言,分体轴承的重要性超越了单纯的功能性;它代表了在各个工程领域提高性能和可靠性的承诺。通过拥抱这些进步,我们可以期待未来的机械比以往任何时候都更高效和可持续地运行。
相关单词
