overhung cylinder

简明释义

外伸汽缸

英英释义

例句

1.Engineers often use an overhung cylinder design for compact applications where space is limited.

工程师们常常在空间有限的紧凑应用中使用悬臂气缸设计。

2.During the maintenance check, we found that the overhung cylinder was misaligned, causing performance issues.

在维护检查中，我们发现悬臂气缸对不齐，导致性能问题。

3.The design of the engine includes an overhung cylinder that improves efficiency by reducing vibrations.

发动机的设计包括一个悬臂气缸，通过减少振动提高效率。

4.The overhung cylinder in the hydraulic system needs to be replaced due to wear and tear.

液压系统中的悬臂气缸因磨损需要更换。

5.The overhung cylinder allows for easier access to the internal components for servicing.

这款悬臂气缸使得内部组件的维修更加方便。

作文

In the field of mechanical engineering, various components play crucial roles in the design and functionality of machines. One such component is the overhung cylinder, which is often used in various applications, including engines and hydraulic systems. Understanding the significance and mechanics of an overhung cylinder can greatly enhance one's knowledge of mechanical systems and their applications.An overhung cylinder refers to a cylindrical component that extends beyond its support structure. This design can be seen in many scenarios, such as in the case of pistons in certain engine configurations or in hydraulic actuators. The positioning of the overhung cylinder allows for effective force application while optimizing space within the machine. However, this design also presents unique challenges, particularly concerning stability and stress distribution.One of the primary advantages of using an overhung cylinder is its ability to provide a compact solution for systems that require significant stroke lengths. In hydraulic applications, for instance, the overhung cylinder can be designed to exert force over a long distance without needing additional space for support. This can lead to more efficient designs, especially in environments where space is at a premium.However, engineers must also consider the potential drawbacks associated with an overhung cylinder. Since the cylinder is not fully supported along its length, it may experience bending moments and increased stress concentrations at the mounting points. This can lead to premature wear or failure if not adequately addressed in the design phase. Therefore, when designing systems that incorporate an overhung cylinder, it is essential to conduct thorough analyses to ensure that the forces acting on the cylinder do not exceed the material limits.Additionally, the dynamics of an overhung cylinder can be complex. When the cylinder is in motion, it may introduce vibrations that can affect the overall performance of the machine. Engineers often employ various damping techniques to mitigate these vibrations, ensuring smoother operation and longer service life for the components involved.Another critical aspect to consider when working with an overhung cylinder is the method of attachment to the main structure. Proper mounting techniques are vital to ensuring that the cylinder remains stable during operation. Various mounting options, such as brackets or flanges, can be utilized depending on the specific application and load requirements.In conclusion, the overhung cylinder is a fundamental component in many mechanical systems, offering both advantages and challenges. Its unique design allows for compact solutions in space-constrained environments, yet it requires careful consideration regarding stability and stress management. By understanding the principles governing an overhung cylinder, engineers can design more efficient and reliable machines that meet the demands of modern applications. As technology continues to advance, the role of the overhung cylinder will undoubtedly evolve, leading to new innovations and improvements in mechanical engineering practices.

在机械工程领域，各种组件在机器的设计和功能中扮演着至关重要的角色。其中一个组件是悬臂气缸，它常用于包括发动机和液压系统在内的各种应用。理解悬臂气缸的重要性和机械原理，可以极大地增强人们对机械系统及其应用的知识。悬臂气缸指的是一个超出其支撑结构的圆柱形组件。这种设计可以在许多场景中看到，例如某些发动机配置中的活塞或液压执行器。悬臂气缸的位置使其能够有效施加力，同时优化机器内部的空间。然而，这种设计也带来了独特的挑战，特别是在稳定性和应力分布方面。使用悬臂气缸的主要优点之一是其能够为需要显著行程长度的系统提供紧凑的解决方案。例如，在液压应用中，悬臂气缸可以设计为在不需要额外支撑空间的情况下施加长距离的力。这可以导致更高效的设计，特别是在空间有限的环境中。然而，工程师还必须考虑与悬臂气缸相关的潜在缺点。由于气缸并未沿其长度得到充分支撑，因此可能会在安装点经历弯矩和增加的应力集中。如果在设计阶段没有充分考虑，这可能导致过早磨损或故障。因此，在设计包含悬臂气缸的系统时，进行彻底分析以确保作用在气缸上的力不会超过材料极限是至关重要的。此外，悬臂气缸的动态特性可能很复杂。当气缸运动时，它可能引入振动，从而影响机器的整体性能。工程师通常采用各种阻尼技术来减轻这些振动，确保组件的更平稳运行和更长的使用寿命。在与悬臂气缸合作时，另一个关键方面是与主结构的连接方式。适当的安装技术对于确保气缸在操作期间保持稳定至关重要。根据具体应用和负载要求，可以使用各种安装选项，例如支架或法兰。总之，悬臂气缸是许多机械系统中的基本组件，提供了优点和挑战。其独特的设计允许在空间受限的环境中实现紧凑的解决方案，但它需要仔细考虑稳定性和应力管理。通过理解悬臂气缸的原理，工程师可以设计出更高效、更可靠的机器，以满足现代应用的需求。随着技术的不断进步，悬臂气缸的作用无疑会不断演变，带来机械工程实践中的新创新和改进。