torsion strength

简明释义

扭转强度

英英释义

例句

1.The engineer calculated the torsion strength of the beam to ensure it could withstand the applied loads.

工程师计算了梁的扭转强度以确保它能够承受施加的荷载。

2.A material's torsion strength is a critical factor in determining its suitability for aerospace applications.

材料的扭转强度是决定其是否适合航空航天应用的关键因素。

3.Testing the torsion strength of the steel rod revealed it could handle significant twisting forces.

对钢棒进行扭转强度测试显示它能够承受显著的扭转力。

4.The torsion strength of the cable was measured to prevent failure during heavy lifting operations.

在重物吊装作业中，为防止失效，测量了电缆的扭转强度。

5.Materials with high torsion strength are essential in the design of automotive components.

具有高扭转强度的材料在汽车部件设计中至关重要。

作文

Torsion strength is a critical property of materials that defines their ability to withstand twisting forces without failing. In engineering and material science, understanding torsion strength (扭转强度) is essential for designing structures and components that can endure various loads during their service life. For instance, when designing a bridge, engineers must consider the torsional forces that may act on the beams as vehicles pass over them. If the torsion strength (扭转强度) of the materials used is insufficient, the bridge could suffer from structural failure, leading to catastrophic consequences.To measure torsion strength (扭转强度), engineers often conduct tests where a sample material is twisted until it breaks. The amount of torque applied at the moment of failure helps determine the material's torsional properties. Different materials exhibit different levels of torsion strength (扭转强度); for example, metals like steel generally have high torsion strength compared to plastics. This property is vital when selecting materials for specific applications where twisting forces are expected.In mechanical design, components such as shafts, gears, and springs frequently experience torsion. Therefore, understanding the torsion strength (扭转强度) of the materials used in these components is crucial for ensuring their reliability and longevity. For example, a drive shaft in a vehicle must possess adequate torsion strength (扭转强度) to transmit power from the engine to the wheels without deforming or breaking. If the shaft were to fail due to inadequate torsion strength, it could lead to severe mechanical failures and safety hazards.Moreover, the concept of torsion strength (扭转强度) extends beyond just mechanical applications. In civil engineering, the torsional behavior of concrete elements, such as beams and columns, is also crucial. Engineers must ensure that these structures can resist torsional moments caused by wind loads or seismic activity. By analyzing the torsion strength (扭转强度) of concrete, engineers can design safer and more efficient buildings and infrastructures.In conclusion, torsion strength (扭转强度) is an essential property that plays a significant role in various fields of engineering and material science. Its importance cannot be overstated, as it directly impacts the safety, performance, and durability of numerous structures and components. As technology advances and new materials are developed, the study of torsion strength (扭转强度) will continue to be a fundamental aspect of engineering education and practice, ensuring that future designs meet the ever-increasing demands of modern society.