seismic stability

简明释义

抗震稳定性

英英释义

例句

1.The research team published a paper on improving seismic stability in bridges.

研究小组发表了一篇关于提高桥梁抗震稳定性的论文。

2.The engineers conducted tests to ensure the building's seismic stability.

工程师进行了测试以确保建筑物的抗震稳定性。

3.In earthquake-prone areas, seismic stability is a crucial factor in construction.

在地震频发地区，抗震稳定性是建筑中的一个关键因素。

4.The city's infrastructure was evaluated for seismic stability after the recent tremors.

在最近的震动后，该市的基础设施被评估了抗震稳定性。

5.Architects must consider seismic stability when designing high-rise buildings.

建筑师在设计高层建筑时必须考虑抗震稳定性。

作文

Seismic stability is a crucial aspect of engineering and architecture, particularly in regions prone to earthquakes. Understanding the concept of seismic stability (地震稳定性) allows engineers to design structures that can withstand the forces generated by seismic activities. In recent years, the importance of seismic stability (地震稳定性) has gained prominence due to increasing urbanization and the rising number of large-scale constructions in earthquake-prone areas. One of the primary goals of ensuring seismic stability (地震稳定性) is to protect human life and property. When an earthquake strikes, the ground shakes violently, which can lead to catastrophic failures in buildings and infrastructure. Engineers use various techniques to enhance seismic stability (地震稳定性), including base isolation, damping systems, and flexible structural designs. Base isolation involves constructing a building on flexible bearings that can absorb seismic energy, allowing the structure to move independently from ground motion. This method significantly reduces the impact of an earthquake on the building’s integrity.Damping systems are another innovative solution for improving seismic stability (地震稳定性). These systems work by dissipating energy during seismic events, reducing the amount of energy transferred to the structure. Various types of dampers, such as viscous and hysteretic dampers, are incorporated into the design to enhance the resilience of buildings against earthquakes. Additionally, flexible structural designs allow buildings to sway rather than break under the pressure of seismic forces. By considering the principles of seismic stability (地震稳定性) during the design phase, architects and engineers can create safer living environments.Moreover, the assessment of seismic stability (地震稳定性) is not limited to new constructions. Retrofitting existing buildings to improve their ability to withstand earthquakes is equally important. Many older structures were built before modern seismic codes were established, making them vulnerable to earthquake damage. Retrofitting involves reinforcing these buildings with modern materials and techniques to enhance their seismic stability (地震稳定性). This process not only prolongs the lifespan of the structure but also ensures the safety of its occupants.In conclusion, the concept of seismic stability (地震稳定性) is vital in the field of construction and urban planning. As we continue to face the challenges posed by natural disasters, the need for resilient structures becomes increasingly apparent. By prioritizing seismic stability (地震稳定性) in our designs, we can safeguard lives and minimize economic losses during seismic events. The collaboration between engineers, architects, and policymakers is essential in promoting practices that enhance seismic stability (地震稳定性) and ensure the safety and sustainability of our built environment.

地震稳定性是工程和建筑中的一个关键方面，特别是在易发生地震的地区。理解seismic stability（地震稳定性）这一概念，使工程师能够设计出能够承受地震活动所产生的力量的结构。近年来，由于城市化进程加快以及在易发生地震地区的大规模建设数量增加，seismic stability（地震稳定性）的重要性愈加突出。确保seismic stability（地震稳定性）的主要目标之一是保护人类生命和财产。当地震发生时，地面剧烈震动，这可能导致建筑物和基础设施的灾难性失败。工程师使用各种技术来增强seismic stability（地震稳定性），包括基础隔震、阻尼系统和柔性结构设计。基础隔震涉及在灵活的支座上建造建筑物，这些支座可以吸收地震能量，使结构能够独立于地面运动而移动。这种方法显著减少了地震对建筑物完整性的影响。阻尼系统是另一种提高seismic stability（地震稳定性）的创新解决方案。这些系统通过在地震事件期间耗散能量来减少传递到结构上的能量。各种类型的阻尼器，如粘性和滞后阻尼器，被纳入设计中，以增强建筑物抵御地震的韧性。此外，柔性结构设计使建筑物在地震力的压力下能够摇摆而不是破裂。通过在设计阶段考虑seismic stability（地震稳定性）的原则，建筑师和工程师可以创造更安全的生活环境。此外，seismic stability（地震稳定性）的评估不仅限于新建筑。对现有建筑进行加固以提高其抗震能力同样重要。许多老旧结构是在现代抗震规范建立之前建造的，使其容易受到地震损害。加固涉及用现代材料和技术加强这些建筑，以提高它们的seismic stability（地震稳定性）。这个过程不仅延长了结构的使用寿命，而且确保了其居住者的安全。总之，seismic stability（地震稳定性）这一概念在建筑和城市规划领域至关重要。随着我们继续面对自然灾害带来的挑战，抗灾结构的需求变得愈发明显。通过在我们的设计中优先考虑seismic stability（地震稳定性），我们可以保护生命并在地震事件中将经济损失降到最低。工程师、建筑师和决策者之间的合作对于促进增强seismic stability（地震稳定性）的实践并确保我们建成环境的安全性和可持续性至关重要。