cylinder wall

简明释义

汽缸壁

英英释义

例句

1.We need to inspect the cylinder wall for any signs of wear or damage.

我们需要检查气缸壁是否有磨损或损坏的迹象。

2.A crack in the cylinder wall can lead to significant engine failure.

在气缸壁上的裂缝可能会导致严重的发动机故障。

3.The mechanic recommended replacing the cylinder wall to improve performance.

机械师建议更换气缸壁以提高性能。

4.The pressure inside the engine increases, causing stress on the cylinder wall.

发动机内部的压力增加，导致对气缸壁的应力增大。

5.During the test, we measured the thickness of the cylinder wall to ensure it meets specifications.

在测试过程中，我们测量了气缸壁的厚度，以确保其符合规格。

作文

The concept of the cylinder wall is fundamental in various fields of engineering and physics. A cylinder wall refers to the surface that forms the boundary of a cylindrical object. This can be seen in many applications, from simple containers to complex machinery. Understanding the properties and functions of a cylinder wall is crucial for designing structures that can withstand various forces and pressures.In mechanical engineering, the cylinder wall plays a pivotal role in the design of engines. For instance, in an internal combustion engine, the cylinder wall must be robust enough to handle the high pressure generated during combustion. The integrity of the cylinder wall is essential for the overall performance of the engine. If the wall is too thin or made from substandard materials, it can lead to catastrophic failures, such as leaks or even explosions. Therefore, engineers must carefully calculate the thickness and material of the cylinder wall to ensure safety and efficiency.Similarly, in civil engineering, the principles of the cylinder wall are applied in the construction of silos, tanks, and other storage facilities. These structures often need to hold large quantities of liquids or granular materials, which exerts significant pressure on the walls. The design of the cylinder wall must account for these forces to prevent structural failure. Engineers utilize various materials, such as reinforced concrete or steel, to create strong and durable cylinder walls that can withstand external pressures.Moreover, the cylinder wall is also a critical component in the field of aerospace engineering. Rocket engines, for example, rely on the cylinder wall to contain the high-pressure gases produced during combustion. The materials used for these walls must not only be strong but also lightweight to maximize efficiency. Engineers often use advanced composites and alloys to achieve the desired balance between strength and weight in the cylinder wall design.In addition to these practical applications, the study of cylinder walls also involves understanding the fluid dynamics around them. When fluids flow over a cylinder wall, various phenomena, such as turbulence and drag, come into play. Researchers analyze these factors to improve the efficiency of systems like pipelines and aerodynamics in vehicles. By optimizing the shape and texture of the cylinder wall, engineers can reduce drag and enhance performance.In conclusion, the cylinder wall is a vital element in numerous engineering disciplines. Its significance spans from mechanical systems to civil constructions and aerospace applications. A thorough understanding of the cylinder wall allows engineers to create safer, more efficient designs that can withstand the demands of their respective environments. As technology advances, the materials and methods used to construct cylinder walls will continue to evolve, leading to innovations that push the boundaries of what is possible in engineering and design.

“圆柱壁”的概念在工程和物理的各个领域都是基础。圆柱壁指的是形成圆柱物体边界的表面。这可以在许多应用中看到，从简单的容器到复杂的机械。理解圆柱壁的性质和功能对于设计能够承受各种力量和压力的结构至关重要。在机械工程中，圆柱壁在发动机设计中发挥着关键作用。例如，在内燃机中，圆柱壁必须足够坚固，以承受燃烧过程中产生的高压。圆柱壁的完整性对发动机的整体性能至关重要。如果壁太薄或材料不合格，可能会导致灾难性的故障，如泄漏甚至爆炸。因此，工程师必须仔细计算圆柱壁的厚度和材料，以确保安全和效率。同样，在土木工程中，圆柱壁的原理应用于筒仓、储罐和其他储存设施的建造。这些结构通常需要容纳大量液体或颗粒材料，这对墙壁施加了显著的压力。圆柱壁的设计必须考虑这些力量，以防止结构失效。工程师采用各种材料，如钢筋混凝土或钢，来创建强大而耐用的圆柱壁，以承受外部压力。此外，圆柱壁在航空航天工程领域也是一个关键组件。例如，火箭发动机依赖于圆柱壁来容纳燃烧过程中产生的高压气体。这些墙壁所使用的材料不仅必须强大，而且还必须轻便，以最大限度地提高效率。工程师们通常使用先进的复合材料和合金，以在圆柱壁设计中实现强度与重量之间的理想平衡。除了这些实际应用之外，圆柱壁的研究还涉及理解其周围的流体动力学。当流体流过圆柱壁时，各种现象，如湍流和阻力，就会发生。研究人员分析这些因素，以提高管道和车辆空气动力学等系统的效率。通过优化圆柱壁的形状和纹理，工程师可以减少阻力并增强性能。总之，圆柱壁是许多工程学科中的重要元素。它的重要性涵盖了机械系统、土木建筑和航空航天应用。对圆柱壁的透彻理解使工程师能够创造出更安全、更高效的设计，以承受各自环境的要求。随着技术的进步，用于构建圆柱壁的材料和方法将继续发展，导致推动工程和设计可能性的创新。