anti-vibration design

简明释义

减振设计

英英释义

例句

1.In the construction of bridges, engineers often implement anti-vibration design 防震设计 to enhance structural integrity.

在桥梁建设中，工程师们通常会实施防震设计 anti-vibration design以增强结构的完整性。

2.For high-performance speakers, an effective anti-vibration design 防震设计 is crucial to maintain sound quality.

对于高性能扬声器，有效的防震设计 anti-vibration design对保持音质至关重要。

3.The drone's anti-vibration design 防震设计 allows for smoother flight and improved camera stability.

无人机的防震设计 anti-vibration design使飞行更平稳，摄像头稳定性更好。

4.The new smartphone features an advanced anti-vibration design 防震设计 that reduces image blur during photography.

这款新智能手机采用了先进的防震设计 anti-vibration design，减少了拍照时图像模糊。

5.The manufacturer claims that their washing machine's anti-vibration design 防震设计 minimizes noise and movement during operation.

制造商声称他们的洗衣机的防震设计 anti-vibration design在操作过程中最小化噪音和移动。

作文

In the modern world, where technology is advancing at an unprecedented pace, the need for effective engineering solutions has never been more critical. One such solution that has gained significant attention in various industries is anti-vibration design. This concept refers to the engineering practices and methodologies used to minimize the impact of vibrations on structures, machinery, and equipment. With the increasing complexity of machines and the environments in which they operate, understanding and implementing anti-vibration design has become essential for ensuring safety, performance, and longevity.Vibrations can arise from numerous sources, including mechanical operations, environmental factors, and even human activities. For instance, in manufacturing plants, heavy machinery can produce substantial vibrations that may lead to equipment malfunction or structural damage over time. The implementation of anti-vibration design helps mitigate these risks by incorporating various techniques, such as the use of vibration isolators, dampers, and tuned mass dampers. These components work together to absorb and dissipate energy generated by vibrations, thus protecting both the machinery and the surrounding structures.One of the most common applications of anti-vibration design is found in the automotive industry. Vehicles are subjected to countless vibrations during operation, which can affect comfort, handling, and overall performance. Engineers employ anti-vibration design principles to create suspension systems that effectively absorb shocks from the road, ensuring a smoother ride for passengers. Additionally, components such as engine mounts and exhaust hangers are designed to reduce vibrations transmitted from the engine to the vehicle chassis, enhancing durability and performance.Another critical area where anti-vibration design plays a vital role is in the construction of buildings and bridges. Structures are often exposed to external forces such as wind, earthquakes, and traffic loads, all of which can induce vibrations. By integrating anti-vibration design techniques, engineers can enhance the resilience of these structures. For example, seismic isolation systems are designed to allow buildings to move independently from ground motion, significantly reducing the risk of damage during an earthquake.Moreover, the importance of anti-vibration design extends to the field of electronics. Many electronic devices, such as smartphones and computers, are sensitive to vibrations that can disrupt their functionality. Engineers utilize anti-vibration design methods to create enclosures and mounts that protect delicate components from shock and vibration. This not only prolongs the lifespan of the devices but also ensures reliable performance in various operating conditions.In conclusion, the significance of anti-vibration design cannot be overstated. As technology continues to evolve, the challenges associated with vibrations will persist. Therefore, it is crucial for engineers and designers to prioritize anti-vibration design in their projects. By doing so, they can enhance the safety, reliability, and efficiency of machines, structures, and electronic devices, ultimately contributing to the advancement of modern society. As we look towards the future, embracing anti-vibration design will undoubtedly play a key role in shaping a more resilient and sustainable world.

在现代世界，科技以空前的速度发展，对有效的工程解决方案的需求比以往任何时候都更为迫切。其中一个在各个行业中受到广泛关注的解决方案是防振设计。这个概念指的是用来最小化振动对结构、机械和设备影响的工程实践和方法。随着机器和它们所处环境的复杂性不断增加，理解和实施防振设计已成为确保安全、性能和耐用性的重要环节。振动可能来自多种来源，包括机械操作、环境因素甚至人类活动。例如，在制造厂，重型机械可能产生大量振动，这可能导致设备故障或结构损坏。实施防振设计通过采用各种技术，例如使用振动隔离器、阻尼器和调谐质量阻尼器，帮助减轻这些风险。这些组件共同作用，以吸收和耗散振动产生的能量，从而保护机械和周围结构。防振设计最常见的应用之一是在汽车工业中。车辆在运行过程中会受到无数振动，这可能影响舒适性、操控性和整体性能。工程师运用防振设计原则来创建有效吸收道路冲击的悬挂系统，从而确保乘客享有更平稳的乘坐体验。此外，诸如发动机支架和排气吊架等组件被设计用于减少从发动机传递到车身的振动，从而增强耐久性和性能。另一个防振设计发挥关键作用的领域是建筑和桥梁的建设。结构经常暴露于风、地震和交通荷载等外部力量，这些力量都会引发振动。通过整合防振设计技术，工程师可以增强这些结构的韧性。例如，抗震隔离系统被设计成允许建筑物独立于地面运动，从而显著降低地震时损坏的风险。此外，防振设计的重要性还延伸到电子领域。许多电子设备，如智能手机和计算机，对振动非常敏感，可能会干扰其功能。工程师利用防振设计方法来创建保护精密组件免受冲击和振动的外壳和支架。这不仅延长了设备的使用寿命，还确保了在各种操作条件下的可靠性能。总之，防振设计的重要性不容小觑。随着科技的不断进步，与振动相关的挑战将持续存在。因此，工程师和设计师在项目中优先考虑防振设计至关重要。通过这样做，他们可以增强机器、结构和电子设备的安全性、可靠性和效率，从而最终推动现代社会的发展。展望未来，拥抱防振设计无疑将在塑造一个更具韧性和可持续发展的世界中发挥关键作用。