frictional damping

简明释义

摩擦阻尼

英英释义

例句

1.The new product features enhanced frictional damping 摩擦阻尼 to improve its durability and performance.

新产品具有增强的摩擦阻尼以提高其耐用性和性能。

2.The researchers studied frictional damping 摩擦阻尼 effects on the stability of the structure during seismic events.

研究人员研究了地震事件中结构的稳定性与摩擦阻尼的关系。

3.By increasing frictional damping 摩擦阻尼, we can minimize the oscillations in the bridge.

通过增加摩擦阻尼，我们可以最小化桥梁的振荡。

4.In the design of the suspension system, frictional damping 摩擦阻尼 plays a crucial role in enhancing ride comfort.

在悬挂系统的设计中，摩擦阻尼在提高乘坐舒适性方面起着至关重要的作用。

5.The engineer explained how frictional damping 摩擦阻尼 can reduce vibrations in mechanical systems.

工程师解释了如何通过摩擦阻尼来减少机械系统中的振动。

作文

Frictional damping is a crucial concept in the field of mechanics and engineering, often applied in various systems to control vibrations and enhance stability. This phenomenon occurs when the relative motion between two surfaces generates resistance due to friction. The effectiveness of frictional damping (摩擦阻尼) can significantly influence the performance and longevity of mechanical systems. For instance, in automotive engineering, frictional damping (摩擦阻尼) is utilized in shock absorbers to minimize the impact of road irregularities on vehicle dynamics. By absorbing energy from shocks, these devices help maintain comfort and safety for passengers while prolonging the life of the vehicle components.Moreover, frictional damping (摩擦阻尼) plays a vital role in structural engineering. In buildings and bridges, it is essential to mitigate the effects of dynamic loads such as wind and earthquakes. Engineers often incorporate dampers that utilize frictional forces to dissipate energy, thereby reducing oscillations and enhancing structural integrity. This application of frictional damping (摩擦阻尼) not only improves safety but also contributes to the resilience of infrastructure against natural disasters.In the realm of robotics, frictional damping (摩擦阻尼) is an important factor in the design of joints and actuators. Robots often operate in unpredictable environments, and the ability to control movement through frictional damping (摩擦阻尼) allows for smoother operation and greater precision. By adjusting the frictional characteristics of joints, engineers can ensure that robots respond effectively to external forces, enhancing their functionality and reliability.The study of frictional damping (摩擦阻尼) also extends to the field of acoustics. In sound engineering, controlling vibrations is essential for achieving high-quality audio. Devices such as speakers and microphones often incorporate materials designed to provide frictional damping (摩擦阻尼) to reduce unwanted resonances and improve sound clarity. This application highlights the versatility of frictional damping (摩擦阻尼) across different domains, from mechanical systems to audio technology.Moreover, understanding the principles behind frictional damping (摩擦阻尼) can lead to innovations in material science. Researchers are constantly exploring new materials that exhibit enhanced frictional properties, which can be applied in various industries. For example, developing composites with tailored frictional characteristics could lead to more efficient energy absorption in automotive applications or improved stability in structural designs. In conclusion, frictional damping (摩擦阻尼) is a multifaceted concept with significant implications across various fields. Its ability to control vibrations and dissipate energy makes it an essential component in engineering and design. As technology continues to advance, the exploration of frictional damping (摩擦阻尼) will likely lead to further innovations that enhance the performance, safety, and durability of systems we rely on every day. Understanding and mastering this concept is vital for engineers and designers who aim to create efficient and resilient solutions in an ever-evolving technological landscape.

摩擦阻尼是机械和工程领域中的一个关键概念，通常应用于各种系统中以控制振动并增强稳定性。当两个表面之间的相对运动由于摩擦产生阻力时，就会发生这种现象。摩擦阻尼的有效性（frictional damping）可以显著影响机械系统的性能和寿命。例如，在汽车工程中，摩擦阻尼被用于减震器，以最小化路面不规则性对车辆动态的影响。通过吸收冲击能量，这些装置有助于保持乘客的舒适和安全，同时延长车辆部件的使用寿命。此外，摩擦阻尼在结构工程中也起着至关重要的作用。在建筑物和桥梁中，减轻风和地震等动态荷载的影响是至关重要的。工程师通常采用利用摩擦力来耗散能量的阻尼器，从而减少振荡并增强结构完整性。摩擦阻尼不仅提高了安全性，还增强了基础设施抵御自然灾害的韧性。在机器人技术领域，摩擦阻尼是关节和执行器设计中的一个重要因素。机器人通常在不可预测的环境中操作，通过摩擦阻尼控制运动可以实现更平滑的操作和更高的精度。通过调整关节的摩擦特性，工程师可以确保机器人有效应对外部力量，从而增强其功能性和可靠性。摩擦阻尼的研究还扩展到声学领域。在声音工程中，控制振动对于实现高质量音频至关重要。扬声器和麦克风等设备通常采用设计用于提供< span>摩擦阻尼的材料，以减少不必要的共鸣并改善声音清晰度。这一应用突显了摩擦阻尼在不同领域的多样性，从机械系统到音频技术。此外，理解摩擦阻尼背后的原理可以推动材料科学的创新。研究人员不断探索具有增强摩擦特性的材料，这些材料可以应用于各个行业。例如，开发具有定制摩擦特性的复合材料可能会导致汽车应用中更高效的能量吸收或结构设计中的更好稳定性。 总之，摩擦阻尼是一个多面向的概念，在各个领域都有重要的影响。它控制振动和耗散能量的能力使其成为工程和设计中的一个重要组成部分。随着技术的不断进步，对摩擦阻尼的探索可能会导致进一步的创新，从而提高我们日常依赖的系统的性能、安全性和耐用性。理解和掌握这一概念对于旨在在不断发展的技术环境中创造高效和韧性解决方案的工程师和设计师来说至关重要。