annular damping vessel

简明释义

油液阻尼箱

英英释义

例句

1.The research focused on improving the efficiency of the annular damping vessel design.

研究集中在提高环形阻尼容器设计的效率上。

2.The engineers designed an annular damping vessel to reduce vibrations in the machinery.

工程师设计了一个环形阻尼容器来减少机器的振动。

3.In the testing phase, the annular damping vessel proved effective in stabilizing the structure.

在测试阶段，环形阻尼容器证明在稳定结构方面非常有效。

4.During the earthquake simulation, the annular damping vessel helped in minimizing damage.

在地震模拟中，环形阻尼容器帮助最小化了损害。

5.We installed multiple annular damping vessels around the reactor to enhance safety measures.

我们在反应堆周围安装了多个环形阻尼容器以增强安全措施。

作文

In the field of engineering and physics, understanding various components and their functions is crucial for designing effective systems. One such component is the annular damping vessel, which plays a significant role in controlling vibrations and enhancing stability in mechanical systems. To comprehend the importance of this device, we must first explore its structure and operational principles. An annular damping vessel is typically designed in a cylindrical shape, featuring an outer and inner wall that creates an annular space between them. This unique geometry allows for the effective absorption of vibrational energy. When mechanical systems operate, they often generate vibrations due to moving parts or external forces. These vibrations can lead to wear and tear, reduced performance, or even catastrophic failures if not properly managed. The annular damping vessel addresses this issue by utilizing fluids or viscoelastic materials within the annular space to dissipate energy. The mechanism behind the annular damping vessel involves the principles of fluid dynamics and material science. When vibrations occur, the fluid inside the vessel moves in response to the oscillations, creating resistance against the motion. This resistance converts kinetic energy from the vibrations into thermal energy, effectively dampening the amplitude of the oscillations. The choice of fluid and the design of the vessel are critical factors that influence the damping performance. Engineers must carefully select these parameters to optimize the system's response to dynamic loads. Applications of the annular damping vessel are diverse and can be found in various industries, including automotive, aerospace, and civil engineering. In automotive applications, for instance, these vessels are integrated into suspension systems to enhance ride comfort and vehicle stability. By reducing the impact of road irregularities, they contribute to a smoother driving experience. Similarly, in aerospace, where precision and reliability are paramount, annular damping vessels are employed to minimize vibrations in aircraft structures and components, ensuring safety and performance. Moreover, the annular damping vessel is also utilized in civil engineering applications, particularly in the design of buildings and bridges. Structures are subjected to dynamic forces such as wind, earthquakes, and human activity. Incorporating these damping vessels into structural designs can significantly improve resilience against such forces. For example, tall buildings equipped with annular damping vessels can sway less during seismic events, providing occupants with greater safety and comfort. In conclusion, the annular damping vessel is an essential component in modern engineering that enhances stability and performance across various applications. Its ability to absorb and dissipate vibrational energy makes it invaluable in preventing damage and ensuring the longevity of mechanical systems. As technology continues to advance, the design and application of annular damping vessels will likely evolve, leading to even more efficient and effective solutions for vibration control. Understanding the principles behind this device not only enriches our knowledge of engineering but also highlights the importance of innovation in addressing complex challenges in our world today.

在工程和物理学领域，理解各种组件及其功能对于设计有效的系统至关重要。其中一个组件是环形阻尼容器，它在控制振动和增强机械系统的稳定性方面发挥着重要作用。要理解该设备的重要性，我们首先必须探讨其结构和操作原理。环形阻尼容器通常设计为圆柱形，具有内外两层壁，在它们之间形成一个环形空间。这种独特的几何形状允许有效吸收振动能量。当机械系统运行时，由于运动部件或外部力量，通常会产生振动。这些振动如果不加以管理，会导致磨损、性能降低，甚至发生灾难性故障。环形阻尼容器通过利用环形空间内的流体或粘弹性材料来解决这个问题，从而消散能量。环形阻尼容器的机制涉及流体动力学和材料科学的原理。当振动发生时，容器内的流体会响应振荡而移动，产生对运动的阻力。这种阻力将振动的动能转化为热能，有效减小振荡的幅度。流体的选择和容器的设计是影响阻尼性能的关键因素。工程师必须仔细选择这些参数，以优化系统对动态负载的响应。环形阻尼容器的应用广泛，涵盖汽车、航空航天和土木工程等多个行业。例如，在汽车应用中，这些容器被集成到悬挂系统中，以增强乘坐舒适性和车辆稳定性。通过减少路面不规则带来的冲击，它们有助于提供更平稳的驾驶体验。同样，在航空航天领域，精度和可靠性至关重要，环形阻尼容器被用于最小化飞机结构和组件的振动，确保安全和性能。此外，环形阻尼容器还用于土木工程应用，特别是在建筑和桥梁的设计中。结构受到风、地震和人类活动等动态力的影响。将这些阻尼容器纳入结构设计中可以显著提高抵御这些力量的韧性。例如，配备环形阻尼容器的高层建筑在地震事件中可以减少摇晃，为居住者提供更大的安全性和舒适性。总之，环形阻尼容器是现代工程中的一个重要组成部分，在各种应用中增强了稳定性和性能。它能够吸收和消散振动能量，使其在防止损坏和确保机械系统的长期运行方面变得不可或缺。随着技术的不断进步，环形阻尼容器的设计和应用可能会不断演变，带来更高效和有效的振动控制解决方案。理解这一设备背后的原理不仅丰富了我们对工程的知识，还突显了创新在应对当今世界复杂挑战中的重要性。