vibration-proof structure

简明释义

防振结构

英英释义

例句

1.A vibration-proof structure is essential for high-performance speakers to deliver clear sound without distortion.

高性能扬声器需要一个防震结构，以提供清晰无失真的声音。

2.The laboratory equipment is designed with a vibration-proof structure to maintain precision during experiments.

实验室设备设计采用了防震结构，以在实验过程中保持精确度。

3.The aerospace industry often relies on vibration-proof structures to ensure the safety of aircraft components.

航空航天工业通常依赖于防震结构来确保飞机部件的安全性。

4.The new smartphone features a vibration-proof structure that protects its internal components from damage.

这款新智能手机采用了防震结构，保护其内部组件不受损坏。

5.In the construction of the bridge, engineers ensured a vibration-proof structure to withstand heavy traffic.

在桥梁的建设中，工程师们确保采用了防震结构以承受重型交通。

作文

In the modern world, where technology and machinery play a vital role in our daily lives, the importance of a vibration-proof structure cannot be overstated. A vibration-proof structure refers to a design or framework that minimizes the impact of vibrations caused by various sources, such as heavy machinery, transportation systems, or even natural events like earthquakes. The significance of this concept is particularly evident in industries such as construction, manufacturing, and aerospace, where precision and safety are paramount.One of the primary reasons for implementing a vibration-proof structure is to enhance the durability of buildings and equipment. Vibrations can lead to wear and tear over time, causing structural damage and reducing the lifespan of materials. For instance, in high-rise buildings, wind-induced vibrations can create discomfort for occupants and potentially compromise the integrity of the structure. By incorporating a vibration-proof structure, engineers can ensure that the building remains stable and safe, while also providing a comfortable living environment.Moreover, a vibration-proof structure plays a crucial role in protecting sensitive equipment. In laboratories and manufacturing facilities, precision instruments are often affected by vibrations, leading to inaccurate measurements and potential failures. For example, in the semiconductor industry, even the slightest vibration can disrupt the delicate processes involved in chip production. Therefore, creating a vibration-proof structure around such equipment can significantly improve operational efficiency and product quality.The application of vibration-proof structures extends beyond just buildings and machinery; it also encompasses transportation systems. Trains, for example, generate significant vibrations during operation, which can affect both the tracks and the passenger experience. Engineers have developed specialized track designs and train suspensions that act as vibration-proof structures to mitigate these effects. This not only enhances the safety and comfort of passengers but also prolongs the life of the railway infrastructure.Furthermore, in the field of aerospace, aircraft must withstand various forces during takeoff, flight, and landing. Engineers design aircraft with vibration-proof structures to ensure that they can endure these stresses without suffering damage. This is critical for maintaining the safety and reliability of air travel, where any failure could have catastrophic consequences.In conclusion, the concept of a vibration-proof structure is integral to modern engineering and architecture. It serves to protect both people and equipment from the adverse effects of vibrations, thereby enhancing safety, durability, and performance across various industries. As technology continues to advance, the development and implementation of effective vibration-proof structures will remain a priority, ensuring that our built environment can withstand the challenges posed by both natural and man-made vibrations. By prioritizing this aspect of design, we can create a safer and more efficient world for future generations.

在现代社会，技术和机械在我们的日常生活中扮演着重要角色，因此“抗振结构”的重要性不容小觑。“抗振结构”是指一种设计或框架，旨在最小化由各种来源引起的振动的影响，例如重型机械、交通系统甚至自然事件（如地震）。这一概念的重要性在建筑、制造和航空航天等行业中尤为明显，因为这些领域对精度和安全性要求极高。实施“抗振结构”的主要原因之一是增强建筑物和设备的耐用性。振动会导致材料随时间的磨损，从而造成结构损坏并缩短材料的使用寿命。例如，在高层建筑中，风引起的振动可能会给居住者带来不适，并可能危及结构的完整性。通过采用“抗振结构”，工程师可以确保建筑物保持稳定和安全，同时提供舒适的居住环境。此外，“抗振结构”在保护敏感设备方面也发挥着至关重要的作用。在实验室和制造设施中，精密仪器常常受到振动的影响，导致测量不准确和潜在故障。例如，在半导体行业，即使是微小的振动也可能干扰芯片生产中的精细过程。因此，在此类设备周围创建“抗振结构”可以显著提高操作效率和产品质量。“抗振结构”的应用不仅限于建筑和机械；它还涵盖了交通系统。例如，火车在运行过程中会产生显著的振动，这可能会影响轨道和乘客体验。工程师开发了专门的轨道设计和火车悬挂系统，作为“抗振结构”来减轻这些影响。这不仅增强了乘客的安全和舒适感，还延长了铁路基础设施的使用寿命。此外，在航空航天领域，飞机必须承受起飞、飞行和着陆期间的各种力量。工程师设计飞机时采用“抗振结构”，以确保它们能够承受这些压力而不会遭受损坏。这对于维护航空旅行的安全和可靠性至关重要，因为任何故障都可能导致灾难性后果。总之，“抗振结构”的概念对于现代工程和建筑至关重要。它旨在保护人和设备免受振动的不利影响，从而提高各个行业的安全性、耐用性和性能。随着技术的不断进步，开发和实施有效的“抗振结构”将继续成为优先事项，确保我们的建筑环境能够承受自然和人为振动带来的挑战。通过优先考虑这一设计方面，我们可以为未来几代人创造一个更安全、更高效的世界。