maximum support clearance

简明释义

最大支承间隙

英英释义

例句

1.To avoid any structural issues, the contractor adhered to the maximum support clearance 最大支撑间隙 outlined in the project specifications.

为了避免任何结构问题，承包商遵循了项目规范中列出的最大支撑间隙 最大支撑间隙。

2.In HVAC systems, the maximum support clearance 最大支撑间隙 is crucial for maintaining efficiency.

在暖通空调系统中，最大支撑间隙 最大支撑间隙对于维持效率至关重要。

3.During the inspection, we measured the maximum support clearance 最大支撑间隙 to confirm it met safety standards.

在检查过程中，我们测量了最大支撑间隙 最大支撑间隙以确认其符合安全标准。

4.The engineer specified the maximum support clearance 最大支撑间隙 to ensure proper airflow in the ventilation system.

工程师指定了最大支撑间隙 最大支撑间隙以确保通风系统的空气流通。

5.The design team calculated the maximum support clearance 最大支撑间隙 required for the new bridge construction.

设计团队计算了新桥建设所需的最大支撑间隙 最大支撑间隙。

作文

In the world of engineering and design, the term maximum support clearance plays a crucial role in ensuring safety and functionality. This phrase refers to the maximum allowable distance between supports or structural elements that can safely bear loads without compromising stability. Understanding this concept is essential for architects, engineers, and construction professionals as it directly impacts the integrity of structures. When designing a building or any other structure, engineers must calculate the maximum support clearance to determine how far apart supports can be placed while still maintaining safety standards. If the supports are too far apart, there is a risk of excessive bending or deformation under load, which could lead to catastrophic failures. Therefore, accurate calculations and adherence to safety regulations are paramount. For instance, consider a bridge that needs to support heavy traffic. Engineers will analyze the materials used, the expected load, and environmental factors to establish the maximum support clearance. This ensures that the bridge can withstand not only the weight of vehicles but also dynamic forces such as wind and seismic activity. The process involves complex mathematical modeling and simulations to predict how the structure will behave under various conditions. Moreover, the maximum support clearance is not just a static measurement; it can vary depending on several factors, including the type of material used, the shape of the structure, and the specific loads applied. For example, steel beams may allow for greater clearances than wooden beams due to their higher strength-to-weight ratio. Thus, understanding the properties of different materials is essential for determining the appropriate support clearance. In addition to structural integrity, the maximum support clearance also has implications for construction practices. During the building phase, workers need to ensure that supports are installed at the correct distances apart. Failure to adhere to the specified clearances can result in costly modifications and potential safety hazards. Therefore, construction teams must be well-trained and equipped with the right tools to measure and install supports accurately. Furthermore, the concept of maximum support clearance extends beyond just traditional buildings and bridges. It is also relevant in various fields such as aerospace, automotive, and even furniture design. For example, in aircraft design, engineers must consider the maximum support clearance between wing supports to ensure optimal aerodynamic performance and structural durability. Similarly, in automotive engineering, the spacing of support structures within a vehicle frame is critical for crash safety and overall performance. In conclusion, the term maximum support clearance is a fundamental aspect of engineering and design that cannot be overlooked. It encompasses the safety, functionality, and efficiency of structures across various industries. By mastering this concept, professionals can create safer and more reliable designs that stand the test of time. As technology advances, the methods for calculating and applying maximum support clearance will continue to evolve, leading to even greater innovations in the field of engineering.

在工程和设计的世界中，术语最大支撑间隙发挥着至关重要的作用，以确保安全性和功能性。这个短语指的是支持或结构元素之间可以安全承受负载而不影响稳定性的最大允许距离。理解这一概念对于建筑师、工程师和施工专业人员至关重要，因为它直接影响到结构的完整性。在设计建筑或其他结构时，工程师必须计算最大支撑间隙以确定支撑可以相距多远，同时仍能保持安全标准。如果支撑之间的距离过大，就会面临在负载下过度弯曲或变形的风险，这可能导致灾难性的故障。因此，准确的计算和遵守安全法规是至关重要的。例如，考虑一座需要承受重型交通的桥梁。工程师将分析所用材料、预期负载和环境因素，以建立最大支撑间隙。这确保了桥梁不仅能够承受车辆的重量，还能抵御风和地震等动态力。这个过程涉及复杂的数学建模和模拟，以预测结构在各种条件下的表现。此外，最大支撑间隙不仅仅是一个静态的测量；它可能会因多种因素而变化，包括所用材料的类型、结构的形状以及施加的特定负载。例如，钢梁可能允许比木梁更大的间隙，因为其更高的强度与重量比。因此，了解不同材料的特性对于确定适当的支撑间隙至关重要。除了结构完整性之外，最大支撑间隙还对建筑实践产生影响。在建筑阶段，工人需要确保支撑以正确的间距安装。未能遵守规定的间隙可能导致昂贵的修改和潜在的安全隐患。因此，施工团队必须经过良好的培训，并配备正确的工具，以准确测量和安装支撑。此外，最大支撑间隙的概念不仅限于传统建筑和桥梁。它在航空航天、汽车甚至家具设计等各个领域也同样相关。例如，在飞机设计中，工程师必须考虑机翼支撑之间的最大支撑间隙，以确保最佳的气动性能和结构耐久性。同样，在汽车工程中，车辆框架内支撑结构的间距对于碰撞安全性和整体性能至关重要。总之，术语最大支撑间隙是工程和设计中的一个基本方面，不能被忽视。它涵盖了各个行业结构的安全性、功能性和效率。通过掌握这一概念，专业人员可以创造出更安全、更可靠的设计，历经时间的考验。随着技术的进步，计算和应用最大支撑间隙的方法将继续演变，从而在工程领域带来更大的创新。