antiseismic construction

简明释义

1. 抗震建筑; 2. 抗震结构;

英英释义

例句

1.After the earthquake, many homeowners decided to retrofit their houses with antiseismic construction 抗震建筑 methods.

地震过后，许多房主决定对他们的房屋进行抗震建筑 antiseismic construction 改造。

2.The city council is investing in antiseismic construction 抗震建筑 for public schools to protect students during seismic events.

市议会正在为公立学校投资抗震建筑 antiseismic construction，以保护学生在地震事件中的安全。

3.Engineers are designing a bridge with antiseismic construction 抗震建筑 features to withstand potential earthquakes.

工程师正在设计一座具有抗震建筑 antiseismic construction 特征的桥，以抵御潜在的地震。

4.Architects are increasingly focusing on antiseismic construction 抗震建筑 principles in their designs.

建筑师在他们的设计中越来越关注抗震建筑 antiseismic construction 原则。

5.The government has mandated that all new buildings must incorporate antiseismic construction 抗震建筑 techniques to ensure public safety.

政府已要求所有新建筑必须采用抗震建筑 antiseismic construction 技术以确保公众安全。

作文

In recent years, the importance of antiseismic construction has become increasingly apparent, especially in regions prone to earthquakes. Antiseismic construction refers to the design and engineering practices that aim to make buildings and infrastructure more resistant to seismic activities. This approach not only protects human lives but also minimizes economic losses during such natural disasters.Earthquakes can strike without warning, causing significant damage to structures and posing serious threats to public safety. Traditional building methods often fail to account for the forces exerted by seismic waves, leading to catastrophic failures during an earthquake. In contrast, antiseismic construction employs various techniques to enhance the stability and resilience of structures.One key aspect of antiseismic construction is the use of flexible materials and innovative design principles. Engineers often incorporate materials that can absorb and dissipate energy, allowing buildings to sway rather than collapse under the pressure of seismic forces. For instance, the use of reinforced concrete, steel frames, and base isolators are common practices in modern antiseismic construction. These methods enable structures to withstand the dynamic loads imposed by earthquakes, reducing the risk of structural failure.Moreover, antiseismic construction also involves careful planning and analysis. Engineers conduct thorough seismic assessments to understand the specific risks associated with a particular location. By analyzing historical earthquake data and geological conditions, they can design buildings that are tailored to withstand potential seismic events. This proactive approach is essential in ensuring the safety and longevity of structures in earthquake-prone areas.In addition to safeguarding buildings, antiseismic construction plays a vital role in protecting infrastructure such as bridges, roads, and utilities. These elements are crucial for emergency response and recovery efforts following an earthquake. By implementing antiseismic construction techniques in infrastructure projects, communities can ensure that vital services remain operational even in the aftermath of a disaster.The economic implications of antiseismic construction are also significant. While the initial costs of implementing these advanced techniques may be higher than traditional methods, the long-term benefits far outweigh the expenses. Buildings designed with antiseismic construction principles are less likely to suffer severe damage during an earthquake, resulting in lower repair costs and reduced downtime for businesses and residents. Furthermore, governments can save on disaster relief expenditures when buildings are constructed to withstand seismic activity.Public awareness and education about antiseismic construction are essential for fostering a culture of safety in earthquake-prone regions. Communities should be encouraged to advocate for stringent building codes and regulations that prioritize antiseismic construction practices. Additionally, homeowners and property developers must be informed about the benefits of investing in antiseismic construction techniques to protect their investments and ensure the safety of occupants.In conclusion, antiseismic construction is a critical aspect of modern architecture and engineering that addresses the challenges posed by earthquakes. By employing innovative design strategies and materials, we can create structures that not only withstand seismic forces but also protect lives and reduce economic losses. As we continue to face the realities of natural disasters, embracing antiseismic construction will be key to building resilient communities capable of enduring the challenges of the future.

近年来，抗震建筑的重要性变得越来越明显，尤其是在地震频发的地区。抗震建筑是指旨在使建筑物和基础设施更能抵御地震活动的设计和工程实践。这种方法不仅保护人类生命，还在自然灾害发生时最大限度地减少经济损失。地震往往在没有警告的情况下发生，对结构造成重大损害，并对公共安全构成严重威胁。传统的建筑方法往往未能考虑地震波施加的力量，导致在地震中发生灾难性故障。相比之下，抗震建筑采用各种技术来增强结构的稳定性和韧性。抗震建筑的一个关键方面是使用灵活的材料和创新的设计原则。工程师通常采用能够吸收和耗散能量的材料，使建筑物在地震力的压力下能够摇摆而不是倒塌。例如，在现代的抗震建筑中，使用钢筋混凝土、钢框架和基础隔震器等是常见的做法。这些方法使结构能够承受地震施加的动态载荷，从而降低结构失效的风险。此外，抗震建筑还涉及仔细的规划和分析。工程师进行全面的地震评估，以了解特定地点相关的风险。通过分析历史地震数据和地质条件，他们可以设计出能够抵御潜在地震事件的建筑。这种前瞻性的方法对于确保地震多发地区建筑的安全性和耐用性至关重要。除了保护建筑物外，抗震建筑在保护桥梁、道路和公用设施等基础设施方面也发挥着重要作用。这些元素对于地震后的紧急响应和恢复工作至关重要。通过在基础设施项目中实施抗震建筑技术，社区可以确保在灾后关键服务仍然可用。抗震建筑的经济影响也相当显著。尽管实施这些先进技术的初始成本可能高于传统方法，但长期收益远远超过这些费用。采用抗震建筑原则设计的建筑在地震中不太可能遭受严重损坏，从而降低了维修成本和企业及居民的停工时间。此外，当建筑物被设计成能够抵御地震活动时，政府可以节省灾后救助支出。公众对抗震建筑的认识和教育对于在地震多发地区培养安全文化至关重要。应鼓励社区倡导严格的建筑规范和优先考虑抗震建筑实践的法规。此外，房主和房地产开发商必须了解投资抗震建筑技术的好处，以保护他们的投资并确保居住者的安全。总之，抗震建筑是现代建筑和工程中的一个关键方面，解决了地震带来的挑战。通过采用创新的设计策略和材料，我们可以创建能够承受地震力量的结构，同时保护生命并减少经济损失。随着我们继续面对自然灾害的现实，拥抱抗震建筑将是建设能够应对未来挑战的韧性社区的关键。