structural performance

简明释义

结构性能

英英释义

例句

1.Innovative materials can significantly enhance the structural performance of modern skyscrapers.

创新材料可以显著提升现代摩天大楼的结构性能。

2.Regular maintenance is essential to ensure the structural performance of aging infrastructure.

定期维护对确保老化基础设施的结构性能至关重要。

3.The engineers conducted a series of tests to evaluate the structural performance of the new bridge design.

工程师们进行了系列测试，以评估新桥设计的结构性能。

4.Understanding the structural performance of materials is crucial in construction projects.

了解材料的结构性能在建筑项目中至关重要。

5.The report highlighted the structural performance of the building under seismic conditions.

报告强调了该建筑在地震条件下的结构性能。

作文

The term structural performance refers to the ability of a structure to withstand loads and forces without failing. This concept is crucial in the fields of civil engineering and architecture, where the safety and functionality of buildings and infrastructures depend heavily on their structural performance. Engineers must consider various factors such as material properties, load conditions, and environmental influences when designing structures to ensure optimal structural performance.One of the primary goals of any construction project is to achieve a balance between safety, durability, and cost-effectiveness. A structure with excellent structural performance can resist natural disasters like earthquakes and hurricanes, providing safety for its occupants. For instance, modern skyscrapers are designed with advanced materials and technologies that enhance their structural performance, allowing them to sway without collapsing during strong winds or seismic activities.In addition to safety, structural performance also impacts the longevity of a building. Structures that are not designed with sufficient consideration for structural performance may suffer from issues such as cracking, deformation, or even catastrophic failure over time. This emphasizes the importance of thorough analysis and testing during the design phase. Engineers often use computer simulations and physical models to predict how a structure will behave under various conditions, ensuring that it meets the required standards of structural performance.Moreover, sustainability has become an increasingly important aspect of structural performance. As the world faces environmental challenges, engineers are tasked with creating structures that not only perform well under stress but also minimize their ecological footprint. This involves selecting sustainable materials and implementing energy-efficient designs that contribute to the overall structural performance while being mindful of the environment.Furthermore, the concept of structural performance extends beyond just buildings. It applies to bridges, roads, and other forms of infrastructure that are vital for transportation and connectivity. The integrity of these structures is essential for public safety and economic stability. Regular maintenance and monitoring are necessary to ensure that their structural performance remains adequate over time. Engineers often conduct inspections and use advanced technologies like sensors to assess the condition of these infrastructures and address any potential issues before they escalate.In conclusion, understanding structural performance is fundamental for anyone involved in construction and engineering. It encompasses a wide range of considerations, including safety, durability, sustainability, and maintenance. As technology advances, the methods for evaluating and improving structural performance continue to evolve, leading to safer and more efficient structures that can withstand the test of time. By prioritizing structural performance, we can ensure that our built environment remains safe, functional, and sustainable for future generations.

术语结构性能指的是一个结构在不发生故障的情况下承受负荷和力量的能力。这个概念在土木工程和建筑领域至关重要，因为建筑物和基础设施的安全性和功能性在很大程度上依赖于它们的结构性能。工程师在设计结构时必须考虑各种因素，如材料特性、负载条件和环境影响，以确保最佳的结构性能。任何建设项目的主要目标之一是实现安全性、耐用性和成本效益之间的平衡。具有优良结构性能的结构能够抵御自然灾害，如地震和飓风，为其居住者提供安全。例如，现代摩天大楼采用先进的材料和技术来增强其结构性能，使其在强风或地震活动中能够摇摆而不倒塌。除了安全性，结构性能还影响建筑的使用寿命。未能充分考虑结构性能的结构可能会随着时间的推移出现裂缝、变形甚至灾难性故障等问题。这强调了在设计阶段进行彻底分析和测试的重要性。工程师通常使用计算机模拟和物理模型来预测结构在各种条件下的表现，确保其符合所需的结构性能标准。此外，可持续性已成为结构性能日益重要的一个方面。随着世界面临环境挑战，工程师被要求创建不仅在压力下表现良好，而且最小化生态足迹的结构。这涉及到选择可持续材料和实施节能设计，这些设计在关注环境的同时也有助于整体结构性能。此外，结构性能的概念不仅适用于建筑物，还适用于桥梁、道路和其他重要的基础设施，这些基础设施对于交通和连接至关重要。这些结构的完整性对公共安全和经济稳定至关重要。定期维护和监测是确保它们的结构性能随着时间的推移仍然足够的必要措施。工程师通常会进行检查，并使用传感器等先进技术来评估这些基础设施的状况，以在潜在问题升级之前解决它们。总之，理解结构性能对任何参与建设和工程的人来说都是基础。它涵盖了广泛的考虑因素，包括安全性、耐用性、可持续性和维护。随着技术的进步，评估和改善结构性能的方法不断发展，导致更安全、更高效的结构能够经受时间的考验。通过优先考虑结构性能，我们可以确保我们的建筑环境在未来几代人中保持安全、功能齐全和可持续。