stringer angle

简明释义

甲板舷边角材

英英释义

例句

1.Adjusting the stringer angle 支撑角度 can significantly affect the load distribution.

调整stringer angle 支撑角度可以显著影响载荷分布。

2.When designing the bridge, engineers calculated the optimal stringer angle 支撑角度 for stability.

在设计桥梁时，工程师计算了最佳的stringer angle 支撑角度以确保稳定性。

3.The architect specified the stringer angle 支撑角度 for the staircase to ensure safety.

建筑师指定了楼梯的stringer angle 支撑角度以确保安全。

4.The stringer angle 支撑角度 must align with the building codes for safety compliance.

为了满足安全合规性，stringer angle 支撑角度必须符合建筑规范。

5.During construction, the team double-checked the stringer angle 支撑角度 for accuracy.

在施工过程中，团队仔细检查了stringer angle 支撑角度以确保准确性。

作文

In the realm of engineering and architecture, precision is paramount. One of the critical components that contribute to the structural integrity of various constructions is the stringer angle. The stringer angle refers to the angle formed by the stringers, which are the longitudinal supports in a structure such as stairs or a bridge. Understanding this concept is essential for engineers and architects alike, as it directly impacts the stability and safety of the structures they design.When designing a staircase, for example, the stringer angle plays a vital role in determining how steep or gentle the staircase will be. A steeper stringer angle might save space but can make the staircase difficult to navigate, especially for individuals with mobility issues. Conversely, a shallower stringer angle may provide easier access but requires more floor space. Therefore, finding the right balance is crucial.Additionally, the stringer angle affects the load distribution across the stringers. A well-calculated stringer angle ensures that weight is evenly distributed, preventing undue stress on any single part of the structure. This is particularly important in larger constructions like bridges, where the safety of countless users depends on the proper alignment and angle of the stringers.Moreover, the materials used in constructing stringers can also influence the effectiveness of the stringer angle. For instance, wooden stringers may have different strength properties compared to steel or concrete ones. Engineers must consider these properties when calculating the ideal stringer angle for their projects. The choice of material, combined with the angle, can either enhance or compromise the overall durability of the structure.In the context of modern architecture, the stringer angle has also found its way into aesthetic considerations. Architects often play with angles to create visually appealing designs that also serve functional purposes. The interplay between the stringer angle and the overall design can lead to innovative structures that challenge traditional architectural norms.Furthermore, understanding the stringer angle is not limited to professionals in the field; it is also beneficial for students studying architecture or engineering. By grasping this concept, students can better appreciate the intricacies involved in creating safe and effective structures. Practical exercises involving the calculation of stringer angle can enhance their learning experience, allowing them to apply theoretical knowledge in real-world scenarios.In conclusion, the stringer angle is a fundamental aspect of structural design that warrants careful consideration. Its implications stretch beyond mere mathematics; they encompass safety, accessibility, and aesthetics in construction. Whether one is an experienced engineer, an aspiring architect, or simply someone interested in the mechanics of building, understanding the stringer angle is crucial for appreciating the complexities of modern construction. As we continue to innovate and push the boundaries of design, the importance of the stringer angle will undoubtedly remain a cornerstone of structural integrity and creativity in architecture.

在工程和建筑领域，精确性至关重要。影响各种建筑结构的结构完整性的关键组成部分之一是stringer angle。stringer angle指的是由纵向支撑构成的角度，这些支撑通常出现在楼梯或桥梁等结构中。理解这一概念对工程师和建筑师而言至关重要，因为它直接影响到他们设计结构的稳定性和安全性。例如，在设计楼梯时，stringer angle在决定楼梯的陡峭程度或平缓程度方面发挥着重要作用。一个较陡的stringer angle可能节省空间，但会使楼梯难以通行，尤其是对行动不便的人来说。相反，一个较浅的stringer angle可能提供更容易的通行，但需要更多的地面空间。因此，找到合适的平衡至关重要。此外，stringer angle还影响着负载在支撑杆上的分布。一个合理计算的stringer angle确保重量均匀分布，防止结构的任何单一部分承受过大的压力。这在大型建筑如桥梁中尤为重要，因为无数用户的安全依赖于支撑杆的正确对齐和角度。此外，构建支撑杆所使用的材料也会影响stringer angle的有效性。例如，木质支撑杆与钢材或混凝土支撑杆可能具有不同的强度特性。工程师在计算其项目的理想stringer angle时必须考虑这些特性。材料的选择与角度的结合，可以增强或削弱结构的整体耐久性。在现代建筑的背景下，stringer angle也进入了美学考量。建筑师经常利用角度的变化来创造既具视觉吸引力又能满足功能需求的设计。stringer angle与整体设计之间的互动可以导致创新结构的出现，挑战传统建筑规范。此外，理解stringer angle不仅限于该领域的专业人士；它对学习建筑或工程的学生也大有裨益。通过掌握这一概念，学生可以更好地欣赏到创建安全有效结构所涉及的复杂性。涉及stringer angle计算的实际练习可以增强他们的学习体验，使他们能够在现实场景中应用理论知识。总之，stringer angle是结构设计的一个基本方面，需要仔细考虑。它的影响超越了简单的数学，它涵盖了建筑中的安全性、可达性和美学。无论是经验丰富的工程师、雄心勃勃的建筑师，还是仅仅对建筑机制感兴趣的人，理解stringer angle对于欣赏现代建筑的复杂性至关重要。随着我们不断创新，推动设计的边界，stringer angle的重要性无疑将继续成为结构完整性和建筑创意的基石。