vibration proof mechanism

简明释义

防振机构

英英释义

例句

1.During the earthquake simulation, the building's vibration proof mechanism proved effective.

在地震模拟中，建筑物的防震机制证明是有效的。

2.To enhance the performance of the drone, engineers installed a vibration proof mechanism to stabilize the camera.

为了提升无人机的性能，工程师安装了一个防震机制以稳定摄像头。

3.The new smartphone features a vibration proof mechanism that ensures durability during drops.

这款新智能手机配备了防震机制，确保在跌落时的耐用性。

4.The industrial machine was designed with a vibration proof mechanism to reduce wear and tear.

这台工业机器设计了一个防震机制以减少磨损。

5.The watch is equipped with a vibration proof mechanism to ensure accurate timekeeping.

这款手表配备了一个防震机制以确保准确计时。

作文

In today's fast-paced technological world, the importance of reliability in machinery cannot be overstated. One crucial aspect that engineers and designers must consider is how to mitigate the effects of vibrations on various components. This is where the concept of a vibration proof mechanism comes into play. A vibration proof mechanism refers to a system or component designed to absorb, dampen, or otherwise counteract vibrations that could lead to mechanical failure or decreased performance. Vibrations can arise from numerous sources, including motor operations, external shocks, or even environmental factors such as earthquakes. When machinery operates, it often generates vibrations that can propagate through the structure, potentially causing wear and tear over time. Without adequate protection, these vibrations can lead to misalignment, increased friction, and ultimately, breakdowns that can be costly and dangerous.To address this issue, engineers employ various strategies to implement vibration proof mechanisms. These may include the use of rubber mounts, springs, and other materials that have inherent damping properties. For example, rubber isolators are commonly used in automotive applications to reduce the transmission of vibrations from the engine to the vehicle's frame. By incorporating a vibration proof mechanism, manufacturers can enhance the longevity and reliability of their products while also improving user comfort.Another innovative approach involves the use of active vibration control systems. These systems utilize sensors to detect vibrations in real-time and then deploy counteractive forces to neutralize them. This technology is particularly useful in high-precision environments, such as in aerospace or medical equipment, where even minor vibrations can lead to significant errors or malfunctions. The integration of such advanced vibration proof mechanisms demonstrates the ongoing evolution of engineering solutions aimed at improving device performance and safety.Moreover, the significance of vibration proof mechanisms extends beyond just mechanical reliability. In many industries, regulatory standards require specific levels of vibration control to ensure safety and compliance. For instance, in construction, heavy machinery must adhere to strict guidelines regarding vibration emissions to protect both operators and nearby structures. Therefore, investing in effective vibration proof mechanisms is not only a technical requirement but also a legal one in many cases.Furthermore, the implementation of vibration proof mechanisms can also lead to increased energy efficiency. When machines operate smoothly without excessive vibrations, they consume less energy and perform better. This efficiency translates to lower operational costs and a reduced environmental footprint, making it a win-win situation for businesses and the planet alike.In conclusion, the role of vibration proof mechanisms in modern engineering is critical for ensuring the functionality, safety, and sustainability of various systems. As technology continues to advance, the development and refinement of these mechanisms will remain a priority for engineers and designers. By focusing on minimizing the impact of vibrations, we can create more reliable and efficient machinery that meets the demands of our ever-evolving world. The future of engineering lies in our ability to innovate and adapt, and vibration proof mechanisms will undoubtedly play a pivotal role in that journey.

在当今快速发展的技术世界中，机械可靠性的重要性不容小觑。工程师和设计师必须考虑的一个关键方面是如何减轻振动对各种组件的影响。这就是防振机制的概念发挥作用的地方。防振机制是指一种旨在吸收、减震或以其他方式抵消可能导致机械故障或性能下降的振动的系统或组件。振动可能来自许多来源，包括电机操作、外部冲击，甚至是地震等环境因素。当机械运行时，通常会产生振动，这些振动可能会传播通过结构，随着时间的推移可能导致磨损。如果没有足够的保护，这些振动可能导致失调、摩擦增加，最终导致昂贵且危险的故障。为了解决这个问题，工程师采用各种策略来实施防振机制。这些可能包括使用橡胶支架、弹簧和其他具有固有阻尼特性的材料。例如，橡胶隔离器通常用于汽车应用，以减少振动从引擎传递到车辆框架。通过结合防振机制，制造商可以增强其产品的耐用性和可靠性，同时提高用户舒适度。另一种创新的方法涉及使用主动振动控制系统。这些系统利用传感器实时检测振动，然后施加反向力以中和它们。这项技术在高精度环境中尤为有用，例如航空航天或医疗设备，在这些环境中，即使是微小的振动也可能导致显著的错误或故障。集成这种先进的防振机制展示了旨在提高设备性能和安全性的工程解决方案的不断演变。此外，防振机制的重要性不仅限于机械可靠性。在许多行业中，监管标准要求特定水平的振动控制，以确保安全和合规性。例如，在建筑行业，重型机械必须遵守有关振动排放的严格指南，以保护操作员和附近的建筑物。因此，投资于有效的防振机制不仅是技术要求，在许多情况下也是法律要求。此外，实施防振机制还可以提高能源效率。当机器平稳运行而没有过多振动时，它们消耗的能源更少，性能更好。这种效率转化为较低的运营成本和减少的环境足迹，使其成为企业和地球的双赢局面。总之，防振机制在现代工程中的作用对于确保各种系统的功能、安全性和可持续性至关重要。随着技术的不断进步，这些机制的发展和完善将继续成为工程师和设计师的优先事项。通过专注于最小化振动的影响，我们可以创建更可靠和高效的机械，以满足我们不断发展的世界的需求。工程的未来在于我们创新和适应的能力，而防振机制无疑将在这一旅程中发挥关键作用。