tensile reinforcement

简明释义

受拉钢筋

英英释义

例句

1.Using tensile reinforcement can significantly enhance the lifespan of a building.

使用抗拉加固可以显著延长建筑物的使用寿命。

2.The engineer specified the use of tensile reinforcement to improve the structural integrity of the bridge.

工程师指定使用抗拉加固以提高桥梁的结构完整性。

3.In concrete structures, tensile reinforcement is essential to withstand tensile forces.

在混凝土结构中，抗拉加固对于承受拉力至关重要。

4.The design team chose steel bars as tensile reinforcement for the new high-rise construction.

设计团队选择钢筋作为新高层建筑的抗拉加固。

5.The contractor installed tensile reinforcement to prevent cracking in the pavement.

承包商安装了抗拉加固以防止路面开裂。

作文

In the field of civil engineering, the concept of tensile reinforcement is crucial for ensuring the structural integrity of various constructions. tensile reinforcement (拉伸增强) refers to the materials used to strengthen concrete structures by enhancing their ability to withstand tensile forces. Concrete, while strong in compression, is relatively weak in tension. This inherent weakness makes it necessary to incorporate additional materials that can absorb tensile stresses and prevent cracking or failure under load. The most common form of tensile reinforcement is steel rebar, which is embedded within concrete to improve its tensile strength. The combination of steel and concrete takes advantage of the compressive strength of concrete and the tensile strength of steel, creating a composite material that performs well under various loading conditions. Engineers must carefully calculate the amount and placement of tensile reinforcement to ensure that the structure can safely support the anticipated loads throughout its lifespan.In addition to traditional steel rebar, new materials such as fiber-reinforced polymers (FRP) are being used as tensile reinforcement in modern construction. These materials offer several advantages, including resistance to corrosion, lightweight properties, and high tensile strength. As infrastructure ages and the need for repairs increases, the use of advanced tensile reinforcement techniques becomes increasingly important. The design process for incorporating tensile reinforcement involves understanding the forces acting on a structure. For example, in a bridge, the weight of the vehicles and the environmental factors such as wind and seismic activity must be considered. Engineers utilize various tools and software to simulate these forces and determine the optimal placement and quantity of tensile reinforcement. This ensures that the structure remains safe and functional over time.Moreover, the quality of tensile reinforcement materials plays a vital role in the overall performance of a structure. Using high-quality steel or advanced composites can significantly enhance the durability and lifespan of a building or bridge. Conversely, poor-quality materials can lead to premature failure, resulting in costly repairs and potential safety hazards.In conclusion, tensile reinforcement (拉伸增强) is an essential component of modern civil engineering that enables structures to withstand various loads and stresses. By employing appropriate materials and techniques, engineers can design safe and durable buildings and infrastructure that meet the demands of society. As technology continues to advance, the methods of implementing tensile reinforcement will evolve, leading to even more efficient and sustainable construction practices. Understanding this concept is paramount for anyone involved in the field of engineering, architecture, or construction management.

在土木工程领域，tensile reinforcement（拉伸增强）的概念对确保各种建筑物的结构完整性至关重要。tensile reinforcement指的是用于增强混凝土结构的材料，以提高其承受拉伸力的能力。混凝土虽然在压缩方面强，但在拉伸方面相对较弱。这种固有的弱点使得必须加入额外的材料，以吸收拉伸应力，防止在负载下开裂或失效。最常见的tensile reinforcement是钢筋，它被嵌入混凝土中以提高其拉伸强度。钢材与混凝土的组合利用了混凝土的抗压强度和钢材的抗拉强度，创造出一种在各种加载条件下表现良好的复合材料。工程师必须仔细计算tensile reinforcement的数量和位置，以确保结构能够安全地承受预期的负载，贯穿其整个生命周期。除了传统的钢筋，现代建筑中还使用诸如纤维增强聚合物（FRP）等新材料作为tensile reinforcement。这些材料提供了多个优点，包括抗腐蚀、轻质特性和高抗拉强度。随着基础设施的老化和维修需求的增加，采用先进的tensile reinforcement技术变得愈发重要。将tensile reinforcement纳入设计过程需要理解作用于结构上的力。例如，在桥梁中，车辆的重量以及风和地震等环境因素都必须考虑。工程师利用各种工具和软件来模拟这些力量，并确定tensile reinforcement的最佳位置和数量，以确保结构在时间上保持安全和功能。此外，tensile reinforcement材料的质量在结构整体性能中起着至关重要的作用。使用高质量的钢材或先进的复合材料可以显著增强建筑物或桥梁的耐久性和使用寿命。相反，劣质材料可能导致提前失效，造成昂贵的维修和潜在的安全隐患。总之，tensile reinforcement（拉伸增强）是现代土木工程的重要组成部分，使结构能够承受各种负载和压力。通过采用适当的材料和技术，工程师可以设计出安全耐用的建筑和基础设施，以满足社会的需求。随着技术的不断进步，实现tensile reinforcement的方法将不断演变，从而导致更高效、更可持续的建筑实践。理解这一概念对于任何参与工程、建筑或施工管理领域的人来说都是至关重要的。