torsion vibration
简明释义
扭转振动
英英释义
Torsion vibration refers to the oscillatory motion of an object around its axis due to twisting forces applied to it. | 扭转振动是指由于施加在物体上的扭转力而导致物体围绕其轴线的振荡运动。 |
例句
1.The monitoring system detected unusual levels of torsion vibration 扭转振动, indicating a potential malfunction.
监控系统检测到异常水平的torsion vibration 扭转振动,这表明可能存在故障。
2.The engineers conducted tests to measure the torsion vibration 扭转振动 of the bridge under heavy loads.
工程师进行了测试,以测量在重载下桥梁的torsion vibration 扭转振动。
3.Research on torsion vibration 扭转振动 helps improve the durability of automotive components.
对torsion vibration 扭转振动的研究有助于提高汽车部件的耐久性。
4.To minimize torsion vibration 扭转振动, the design included dampers and flexible couplings.
为了最小化torsion vibration 扭转振动,设计中包含了阻尼器和柔性联轴器。
5.Excessive torsion vibration 扭转振动 can lead to structural failure in rotating machinery.
过度的torsion vibration 扭转振动可能导致旋转机械的结构失效。
作文
Torsion vibration is a fascinating phenomenon that occurs in various mechanical systems. It refers to the oscillations that happen when an object twists about its axis. This type of vibration can be found in numerous applications, from automotive engineering to civil structures. Understanding torsion vibration (扭转振动) is crucial for engineers and designers as it can significantly impact the performance and safety of machines and structures.In mechanical systems, torsion vibration (扭转振动) often arises due to the rotation of shafts or other components. For instance, in an automobile, the drive shaft experiences torsion vibration (扭转振动) as the engine generates power and transmits it to the wheels. If not properly managed, these vibrations can lead to fatigue and failure of materials, which can have catastrophic consequences.To analyze torsion vibration (扭转振动), engineers often use mathematical models and simulations. These tools help predict how a system will behave under different conditions, allowing for better design choices. For example, by understanding the frequency and amplitude of torsion vibration (扭转振动), engineers can select materials that are more resistant to such stresses, thereby enhancing the durability of the product.Moreover, torsion vibration (扭转振动) is not limited to mechanical systems; it can also be observed in structural engineering. Buildings and bridges must be designed to withstand various forces, including those that cause twisting motions. In seismic zones, for example, structures are particularly vulnerable to torsion vibration (扭转振动) during an earthquake. Engineers employ various strategies, such as adding dampers or using flexible materials, to mitigate these effects and ensure the safety of occupants.Understanding the implications of torsion vibration (扭转振动) extends beyond just preventing failures. It also plays a vital role in the efficiency of machines. Excessive vibrations can lead to energy losses and increased wear and tear. By optimizing designs to minimize torsion vibration (扭转振动), manufacturers can enhance the performance of their products, leading to greater customer satisfaction and reduced operational costs.In conclusion, torsion vibration (扭转振动) is an essential concept in both mechanical and structural engineering. Its effects can be profound, influencing everything from the longevity of a vehicle's components to the stability of a skyscraper. As technology advances, the ability to analyze and manage torsion vibration (扭转振动) will continue to improve, leading to safer and more efficient designs. Engineers must remain vigilant in studying this phenomenon to ensure that the systems they create are capable of withstanding the challenges posed by torsion vibration (扭转振动) and to promote innovation across various industries.
扭转振动是一个迷人的现象,发生在各种机械系统中。它指的是物体绕其轴线扭曲时发生的振荡。这种振动类型可以在多个应用中找到,从汽车工程到土木结构。理解扭转振动(torsion vibration)对工程师和设计师至关重要,因为它会显著影响机器和结构的性能与安全性。在机械系统中,扭转振动(torsion vibration)通常由于轴或其他组件的旋转而产生。例如,在汽车中,驱动轴在发动机产生动力并将其传递到车轮时,会经历扭转振动(torsion vibration)。如果不加以管理,这些振动可能导致材料疲劳和失效,后果可能是灾难性的。为了分析扭转振动(torsion vibration),工程师通常使用数学模型和模拟。这些工具有助于预测系统在不同条件下的行为,从而允许更好的设计选择。例如,通过理解扭转振动(torsion vibration)的频率和幅度,工程师可以选择对这种应力更具抵抗力的材料,从而增强产品的耐用性。此外,扭转振动(torsion vibration)不仅限于机械系统;它也可以在结构工程中观察到。建筑物和桥梁必须设计成能够承受各种力量,包括导致扭转运动的力量。在地震区,例如,结构在地震期间特别容易受到扭转振动(torsion vibration)的影响。工程师采用各种策略,如增加阻尼器或使用柔性材料,以减轻这些影响并确保居住者的安全。理解扭转振动(torsion vibration)的影响不仅限于防止故障。它还在机器的效率中发挥着重要作用。过度的振动可能导致能量损失和磨损增加。通过优化设计以最小化扭转振动(torsion vibration),制造商可以提高产品的性能,从而提高客户满意度并降低运营成本。总之,扭转振动(torsion vibration)是机械和结构工程中的一个重要概念。它的影响可能深远,影响从车辆部件的寿命到摩天大楼的稳定性。随着技术的进步,分析和管理扭转振动(torsion vibration)的能力将继续提高,从而导致更安全和更高效的设计。工程师必须保持警惕,研究这一现象,以确保他们创造的系统能够承受扭转振动(torsion vibration)带来的挑战,并促进各个行业的创新。
相关单词
