design basis earthquake

简明释义

设计依据地震

英英释义

例句

1.Our project must adhere to the local codes regarding the design basis earthquake 设计基准地震 requirements.

我们的项目必须遵循关于设计基准地震 设计基准地震要求的当地规范。

2.The engineers calculated the potential impact of a design basis earthquake 设计基准地震 on the new building's structure.

工程师们计算了新的建筑结构在遭遇设计基准地震 设计基准地震时可能受到的影响。

3.The design basis earthquake 设计基准地震 is a critical factor in determining the seismic design of bridges.

在确定桥梁的抗震设计时，设计基准地震 设计基准地震是一个关键因素。

4.The design basis earthquake 设计基准地震 level was established based on historical seismic data.

根据历史地震数据，设定了设计基准地震 设计基准地震等级。

5.During the safety assessment, we need to consider the design basis earthquake 设计基准地震 for this nuclear facility.

在安全评估中，我们需要考虑该核设施的设计基准地震 设计基准地震。

作文

In the field of civil engineering and construction, the term design basis earthquake refers to a set of seismic criteria used to design structures that can withstand the forces generated by earthquakes. This concept is crucial for ensuring the safety and resilience of buildings, bridges, and other infrastructure in seismically active regions. The design basis earthquake is determined by analyzing historical seismic data, geological conditions, and the specific location of the structure. Engineers utilize this information to create designs that meet or exceed the expected seismic demands. The importance of the design basis earthquake cannot be overstated. With the increasing frequency of earthquakes around the globe, it is essential for engineers to account for potential seismic events when designing structures. A well-defined design basis earthquake provides a benchmark for evaluating the performance of a structure during an earthquake. For instance, if a building is designed to withstand a design basis earthquake with a magnitude of 7.0, it should remain standing and functional after such an event occurs.Moreover, the design basis earthquake helps in establishing codes and standards that govern construction practices. These codes are developed by national and international organizations, which compile extensive research on seismic activity and its effects on structures. By adhering to these guidelines, engineers can ensure that their designs are not only compliant with safety regulations but also capable of protecting lives and property.When determining the design basis earthquake, various factors are considered, including the type of soil, the proximity to fault lines, and the intended use of the structure. For example, a hospital or school may require a higher level of seismic safety compared to a warehouse. This differentiation ensures that critical facilities remain operational during and after an earthquake, thereby serving the community effectively.In recent years, advancements in technology have allowed for more accurate modeling of seismic events. Engineers can now simulate different earthquake scenarios and assess how various designs would perform under those conditions. This capability enhances the reliability of the design basis earthquake and contributes to the overall safety of constructed environments.In conclusion, the design basis earthquake is a fundamental aspect of modern engineering practices in earthquake-prone areas. It serves as a critical guideline for designing structures that can endure seismic forces while safeguarding human life and property. As our understanding of seismic risks continues to evolve, so too will the methodologies used to establish the design basis earthquake. Ultimately, the goal remains the same: to create resilient infrastructure that can withstand the unpredictable nature of earthquakes and protect communities from their devastating impacts.

在土木工程和建筑领域，术语设计基础地震指的是一组用于设计能够抵御地震产生的力量的结构的抗震标准。这个概念对于确保建筑、桥梁和其他基础设施在地震活跃地区的安全性和韧性至关重要。设计基础地震通过分析历史地震数据、地质条件和结构的具体位置来确定。工程师利用这些信息创建满足或超过预期抗震要求的设计。 设计基础地震的重要性不容小觑。随着全球地震频率的增加，工程师在设计结构时考虑潜在的地震事件变得至关重要。明确的设计基础地震为评估结构在地震期间的表现提供了基准。例如，如果一座建筑被设计成能够承受7.0级的设计基础地震，那么在发生这样的事件后，它应该保持竖立并且功能正常。此外，设计基础地震有助于建立管理建筑实践的规范和标准。这些规范由国家和国际组织制定，这些组织汇编了关于地震活动及其对结构影响的广泛研究。通过遵循这些指导方针，工程师可以确保他们的设计不仅符合安全法规，还能够保护生命和财产。在确定设计基础地震时，会考虑多种因素，包括土壤类型、与断层线的距离以及结构的预期用途。例如，医院或学校可能需要比仓库更高水平的抗震安全。这种差异化确保关键设施在地震期间和之后保持正常运转，从而有效服务社区。近年来，技术的进步使得对地震事件的建模更加准确。工程师现在可以模拟不同的地震场景，并评估各种设计在这些条件下的表现。这种能力增强了设计基础地震的可靠性，并有助于构建环境的整体安全性。总之，设计基础地震是现代抗震设计实践的一个基本方面，尤其是在地震频发地区。它作为设计能够承受地震力量的结构的关键指南，同时保护人类生命和财产。随着我们对抗震风险的理解不断发展，用于建立设计基础地震的方法论也将不断演变。最终目标仍然是创造出能够抵御地震不可预测特性的韧性基础设施，保护社区免受其破坏性影响。