aseismic structures

简明释义

抗震结构

英英释义

例句

1.The architect specialized in designing aseismic structures for high-risk areas.

这位建筑师专门设计高风险地区的抗震结构。

2.Retrofitting older buildings into aseismic structures is crucial for urban safety.

将老建筑改造成抗震结构对城市安全至关重要。

3.The city implemented new regulations requiring all buildings to be aseismic structures.

该市实施了新规定，要求所有建筑物都必须是抗震结构。

4.Investing in aseismic structures can save lives during seismic events.

投资于抗震结构可以在地震事件中拯救生命。

5.Engineers design aseismic structures to withstand earthquakes.

工程师设计抗震结构以抵御地震。

作文

In the realm of civil engineering and architecture, the term aseismic structures refers to buildings and infrastructures designed specifically to withstand seismic activities, such as earthquakes. The importance of aseismic structures cannot be overstated, especially in regions that are prone to seismic events. These structures are engineered to absorb and dissipate the energy released during an earthquake, thereby minimizing damage and ensuring the safety of occupants. To understand how aseismic structures function, it is essential to delve into the principles of seismic design. Engineers employ various techniques to enhance a building's resilience against earthquakes. One common method is the use of flexible materials that allow the structure to sway without collapsing. This flexibility helps to distribute the forces exerted by seismic waves, reducing the risk of structural failure.Another critical aspect of aseismic structures is their foundation. A robust foundation is crucial for maintaining stability during an earthquake. Engineers often design deep foundations or use base isolators that enable the building to move independently from ground motion. This technology effectively isolates the structure from seismic forces, providing an additional layer of protection.Moreover, the shape and configuration of aseismic structures play a significant role in their performance during an earthquake. Buildings with symmetrical designs tend to perform better than those with irregular shapes. This is because symmetrical structures distribute loads evenly, reducing the likelihood of torsional movements that can lead to severe damage.The implementation of aseismic structures has proven to be effective in numerous high-risk areas worldwide. For instance, cities like Tokyo and San Francisco have adopted stringent building codes that mandate the construction of aseismic structures. These regulations have significantly reduced the impact of earthquakes on urban environments, saving lives and minimizing economic losses.Despite the advancements in technology and engineering practices, challenges remain in the field of seismic design. One of the primary obstacles is the cost associated with implementing aseismic structures. While the long-term benefits of these structures are evident, the initial investment can be substantial, deterring some developers from adopting such measures. Additionally, there is a continuous need for research and innovation in the field of seismic engineering. As our understanding of earthquakes evolves, so too must our approaches to designing aseismic structures. New materials, construction techniques, and technologies are constantly being developed to enhance the performance of structures under seismic loads.In conclusion, aseismic structures represent a vital aspect of modern engineering aimed at protecting lives and property in earthquake-prone areas. By incorporating advanced design principles, innovative materials, and rigorous building codes, we can create safer environments for current and future generations. Investing in aseismic structures is not merely a choice but a necessity in safeguarding communities against the unpredictable nature of seismic events.

在土木工程和建筑领域，短语抗震结构指的是专门设计用于抵御地震活动（如地震）的建筑物和基础设施。抗震结构的重要性不容小觑，尤其是在地震频发的地区。这些结构经过工程设计，以吸收和消散地震释放的能量，从而最大限度地减少损害并确保居住者的安全。要理解抗震结构的功能，有必要深入研究抗震设计的原则。工程师采用各种技术来增强建筑物抵御地震的能力。一种常见的方法是使用灵活的材料，使结构能够在不倒塌的情况下摇摆。这种灵活性有助于分散地震波施加的力量，降低结构失效的风险。抗震结构的另一个关键方面是其基础。坚固的基础对于在地震期间保持稳定至关重要。工程师通常设计深基础或使用基础隔离器，使建筑物能够独立于地面运动而移动。这项技术有效地将结构与地震力隔离，为保护提供了额外的防护层。此外，抗震结构的形状和配置在地震期间的性能中也起着重要作用。对称设计的建筑物往往比不规则形状的建筑物表现更好。这是因为对称结构均匀分配荷载，减少了扭转运动导致严重损坏的可能性。在全球众多高风险地区，实施抗震结构已被证明是有效的。例如，东京和旧金山等城市已采用严格的建筑规范，要求建设抗震结构。这些规定显著减少了地震对城市环境的影响，拯救了生命并最小化了经济损失。尽管在技术和工程实践方面取得了进展，但抗震设计领域仍然面临挑战。主要障碍之一是实施抗震结构所需的成本。尽管这些结构的长期利益显而易见，但初期投资可能相当可观，这使一些开发商不愿采取此类措施。此外，抗震工程领域对研究和创新的持续需求也存在。随着我们对地震的理解不断发展，我们的抗震结构设计方法也必须随之演变。新材料、施工技术和技术不断被开发，以增强结构在地震荷载下的性能。总之，抗震结构代表了现代工程的重要组成部分，旨在保护地震频发地区的生命和财产。通过结合先进的设计原则、创新材料和严格的建筑规范，我们可以为当前和未来的世代创造更安全的环境。投资于抗震结构不仅仅是一种选择，而是保障社区免受地震事件不可预测性质的必要措施。