structural limits
简明释义
结构强度极限
英英释义
Structural limits refer to the maximum capacity or boundaries within which a structure can safely operate without failure or significant deformation. | 结构限制是指一个结构在不发生故障或显著变形的情况下可以安全操作的最大容量或边界。 |
例句
1.The team conducted tests to determine the structural limits of the new composite materials.
团队进行了测试,以确定新复合材料的结构限制。
2.In construction, understanding the structural limits of a building is crucial for long-term durability.
在建筑中,理解建筑的结构限制对长期耐用性至关重要。
3.The architect had to revise the plans due to the structural limits imposed by local regulations.
由于当地法规施加的结构限制,建筑师不得不修改计划。
4.The engineer explained that the design must adhere to the structural limits of the materials used to ensure safety.
工程师解释说,设计必须遵循所用材料的结构限制以确保安全。
5.Before proceeding, we need to assess the structural limits of the existing framework.
在继续之前,我们需要评估现有框架的结构限制。
作文
In today's rapidly evolving world, the concept of structural limits is becoming increasingly relevant across various fields, including architecture, engineering, and even social sciences. Understanding these limits can help us navigate the complexities of design, construction, and societal frameworks. Structural limits refer to the boundaries or constraints that define the capabilities and performance of a system, structure, or society. For instance, in engineering, these limits might pertain to the maximum load a bridge can bear before it fails. In a social context, structural limits may relate to the institutional frameworks that dictate the functionality and efficiency of social systems.When we consider architecture, the structural limits of a building are crucial for ensuring safety and stability. Architects must take into account the materials they use, the design of the structure, and the environmental factors that could impact its integrity. For example, the height of a skyscraper is often determined by its structural limits, which include the strength of the materials used and the engineering techniques employed. If these limits are exceeded, the consequences can be catastrophic, leading to structural failure and endangering lives.Moreover, the notion of structural limits extends beyond physical structures. In social sciences, researchers examine how structural limits influence societal behavior and interactions. For example, economic systems operate within certain structural limits that dictate how resources are allocated and distributed. These limits can manifest as laws, regulations, or cultural norms that shape individual and collective behavior. Understanding these limits can provide insights into why certain social issues persist and how they can be addressed.In the realm of technology, structural limits also play a significant role. As we push the boundaries of innovation, we often encounter technical limitations that challenge our progress. For instance, in the field of computing, there are structural limits related to processing power and data storage that can impede advancements in artificial intelligence and machine learning. Recognizing these limits allows engineers and developers to innovate within feasible parameters, ultimately leading to more sustainable and effective solutions.Furthermore, acknowledging structural limits encourages a mindset of adaptability and resilience. Rather than viewing these limits as obstacles, we can see them as opportunities for creativity and problem-solving. For example, when faced with the structural limits of a particular material, engineers might explore alternative materials or innovative design approaches that enhance performance while staying within those limits. This adaptive approach can lead to breakthroughs that redefine what is possible within a given framework.In conclusion, the concept of structural limits is multifaceted and applicable across various disciplines. By understanding these limits, we can make informed decisions that promote safety, efficiency, and sustainability. Whether in engineering, social sciences, or technology, recognizing the structural limits allows us to innovate responsibly and effectively. As we continue to advance in our respective fields, let us embrace these limits not as barriers, but as guiding principles that inspire us to think creatively and push the boundaries of what we can achieve.
在当今快速发展的世界中,“结构限制”这一概念在建筑、工程甚至社会科学等多个领域变得越来越相关。理解这些限制可以帮助我们应对设计、建造和社会框架的复杂性。“结构限制”指的是定义系统、结构或社会能力和性能的边界或约束。例如,在工程学中,这些限制可能涉及桥梁在失效之前能够承受的最大负载。在社会背景中,“结构限制”可能与规定社会系统功能和效率的制度框架有关。当我们考虑建筑时,建筑物的“结构限制”对确保安全和稳定至关重要。建筑师必须考虑他们使用的材料、结构的设计以及可能影响其完整性的环境因素。例如,摩天大楼的高度通常由其“结构限制”决定,这包括所用材料的强度和采用的工程技术。如果超过这些限制,后果可能是灾难性的,导致结构失败并危及生命。此外,“结构限制”的概念超越了物理结构。在社会科学中,研究人员考察“结构限制”如何影响社会行为和互动。例如,经济系统在某些“结构限制”下运作,这些限制决定了资源的分配和分发。这些限制可能表现为法律、法规或塑造个体和集体行为的文化规范。理解这些限制可以提供关于某些社会问题为何持续存在以及如何解决它们的见解。在技术领域,“结构限制”也发挥着重要作用。当我们推动创新的边界时,常常会遇到技术限制,这些限制挑战我们的进步。例如,在计算机领域,与处理能力和数据存储相关的“结构限制”可能会阻碍人工智能和机器学习的进展。认识到这些限制使工程师和开发者能够在可行的参数内进行创新,最终导致更可持续和有效的解决方案。此外,承认“结构限制”鼓励适应性和韧性的心态。与其将这些限制视为障碍,我们不如将其视为创造力和解决问题的机会。例如,当面临特定材料的“结构限制”时,工程师可能会探索替代材料或创新设计方法,以增强性能,同时保持在这些限制之内。这种适应性的方法可以导致突破,重新定义在给定框架内可能实现的目标。总之,“结构限制”的概念是多方面的,并且适用于各个学科。通过理解这些限制,我们可以做出明智的决策,促进安全、效率和可持续性。无论是在工程、社会科学还是技术领域,认识到“结构限制”使我们能够负责任地和有效地创新。随着我们在各自领域的不断进步,让我们将这些限制视为指导原则,而不是障碍,激励我们创造性思考,推动我们所能实现的边界。
相关单词
