tilting pad

简明释义

扇形支座

英英释义

例句

1.The tilting pad system allows for better load distribution in high-speed applications.

在高速应用中，倾斜垫片系统能够实现更好的载荷分布。

2.During maintenance, we checked the wear on the tilting pad to ensure optimal performance.

在维护期间，我们检查了倾斜垫片的磨损情况，以确保最佳性能。

3.We replaced the old tilting pad with a more durable material to extend its lifespan.

我们用更耐用的材料替换了旧的倾斜垫片以延长其使用寿命。

4.The tilting pad design minimizes friction and heat generation during operation.

该倾斜垫片设计在操作过程中最小化摩擦和热量产生。

5.The engineer designed the turbine with a new type of tilting pad to improve efficiency.

工程师设计了一个新的涡轮，采用了新型的倾斜垫片以提高效率。

作文

The engineering world is filled with intricate designs and innovative solutions, one of which is the concept of a tilting pad. This component plays a crucial role in various machinery, particularly in the realm of rotating equipment such as turbines and generators. A tilting pad refers to a type of bearing system where the pads are allowed to tilt, enabling them to adjust to the load conditions dynamically. This feature is essential for maintaining optimal performance and minimizing wear over time.In traditional bearing systems, the pads are fixed and do not adapt to changes in load or alignment. However, with the introduction of the tilting pad design, engineers have developed a solution that enhances the efficiency of machinery. The ability of the pads to tilt means that they can distribute the load more evenly across their surface, reducing stress concentrations and prolonging the life of the bearings.The application of tilting pads can be seen in various industries, including power generation, oil and gas, and manufacturing. For instance, in a steam turbine, the use of tilting pads allows for smoother operation by accommodating any misalignment that may occur due to thermal expansion or mechanical vibrations. This adaptability leads to reduced friction and heat generation, ultimately improving the overall efficiency of the turbine.Moreover, the design of tilting pads can also contribute to energy savings. By minimizing friction and wear, these bearings require less energy to operate, which is particularly important in large-scale industrial applications where energy costs can be significant. Additionally, the reduced maintenance requirements associated with tilting pads mean that downtime for repairs is minimized, allowing for continuous operation and increased productivity.The engineering behind tilting pads is a fascinating blend of physics and material science. Engineers must consider factors such as load capacity, pad geometry, and lubrication to optimize the performance of these bearings. Advanced materials are often used to manufacture tilting pads, ensuring that they can withstand high temperatures and pressures while maintaining their structural integrity.In conclusion, the tilting pad is a remarkable innovation in bearing technology that has revolutionized the way we approach rotating machinery. Its ability to adapt to changing conditions makes it an invaluable component in many industrial applications. As technology continues to advance, we can expect to see even more improvements in the design and functionality of tilting pads, further enhancing the efficiency and reliability of the machinery we depend on every day.

工程界充满了复杂的设计和创新的解决方案，其中之一就是“tilting pad”的概念。这个组件在各种机械中扮演着至关重要的角色，特别是在涡轮机和发电机等旋转设备领域。“tilting pad”指的是一种轴承系统，其中垫片可以倾斜，使其能够动态地适应负载条件。这一特性对于保持最佳性能和最小化磨损至关重要。在传统的轴承系统中，垫片是固定的，不会适应负载或对齐的变化。然而，随着“tilting pad”设计的引入，工程师们开发出了一种增强机械效率的解决方案。垫片的倾斜能力意味着它们可以更均匀地分配负载，减少应力集中，从而延长轴承的使用寿命。“tilting pads”的应用可以在多个行业中看到，包括发电、石油和天然气以及制造业。例如，在蒸汽涡轮中，使用“tilting pads”可以通过适应由于热膨胀或机械振动可能发生的任何不对称，来实现更平稳的运行。这种适应性降低了摩擦和热量产生，最终提高了涡轮的整体效率。此外，“tilting pads”的设计还可以帮助节省能源。通过最小化摩擦和磨损，这些轴承需要更少的能量来操作，这在大型工业应用中尤为重要，因为能源成本可能会很高。此外，与“tilting pads”相关的维护需求减少意味着维修的停机时间最小化，从而允许连续操作并提高生产力。“tilting pads”背后的工程技术是物理学和材料科学的迷人结合。工程师必须考虑负载能力、垫片几何形状和润滑等因素，以优化这些轴承的性能。通常使用先进材料制造“tilting pads”，确保它们能够承受高温和高压，同时保持结构完整性。总之，“tilting pad”是一项令人瞩目的轴承技术创新，彻底改变了我们处理旋转机械的方式。它适应变化条件的能力使其成为许多工业应用中不可或缺的组件。随着技术的不断进步，我们可以期待在“tilting pads”的设计和功能上看到更多的改进，进一步提高我们日常依赖的机械的效率和可靠性。