mechanical stabilisation

简明释义

机械稳定处理

英英释义

例句

1.During the flight test, mechanical stabilisation was critical for maintaining the aircraft's balance.

在飞行测试中，机械稳定对维持飞机的平衡至关重要。

2.In the construction of bridges, mechanical stabilisation helps to withstand environmental forces.

在桥梁建设中，机械稳定有助于抵御环境力量。

3.The engineer implemented mechanical stabilisation to enhance the structural integrity of the building.

工程师实施了机械稳定以增强建筑物的结构完整性。

4.The robotics team used mechanical stabilisation to prevent the robot from tipping over during operations.

机器人团队使用机械稳定来防止机器人在操作过程中倾倒。

5.The application of mechanical stabilisation in this project reduced vibrations significantly.

在这个项目中应用的机械稳定显著减少了振动。

作文

In the field of engineering and construction, the term mechanical stabilisation refers to the use of mechanical means to enhance the stability of structures and materials. This concept is crucial in various applications, including civil engineering, aerospace, and even automotive industries. The idea behind mechanical stabilisation is to improve the load-bearing capacity and overall performance of a structure by employing mechanical methods such as reinforcements, supports, and other stabilizing devices.One of the most common applications of mechanical stabilisation can be seen in the construction of buildings and bridges. Engineers often utilize steel beams or reinforced concrete to provide additional strength to these structures. By incorporating these mechanical elements, the risk of structural failure due to external forces, such as wind or earthquakes, is significantly reduced. This not only ensures the safety of the occupants but also prolongs the lifespan of the structure.Moreover, mechanical stabilisation is also vital in the field of soil mechanics. When constructing foundations, engineers must consider the stability of the soil. Techniques such as soil nailing, where steel rods are inserted into the ground to provide additional support, exemplify how mechanical stabilisation can be effectively applied to enhance soil stability. This process helps prevent landslides and other soil-related issues that could jeopardize the integrity of the structure above.In the aerospace industry, mechanical stabilisation plays a critical role in ensuring the safety and performance of aircraft. For instance, the wings of an airplane are designed with specific mechanical features that allow them to withstand turbulence and other aerodynamic forces during flight. Engineers conduct extensive testing and simulations to ensure that these components are adequately stabilized, which is essential for the overall safety of air travel.Furthermore, in automotive engineering, mechanical stabilisation is used to enhance vehicle stability and control. The suspension systems in cars, for example, are designed to absorb shocks and maintain contact between the tires and the road. By utilizing various mechanical components such as shock absorbers and springs, manufacturers can ensure that vehicles remain stable during turns and over uneven surfaces. This not only improves the driving experience but also enhances safety for passengers and pedestrians alike.In summary, mechanical stabilisation is a fundamental concept in various engineering disciplines that involves the use of mechanical methods to enhance stability and performance. Whether it is in the construction of buildings, the design of aircraft, or the engineering of vehicles, the principles of mechanical stabilisation play a crucial role in ensuring safety and longevity. As technology continues to advance, the methods and techniques used for mechanical stabilisation will likely evolve, leading to even more innovative solutions in engineering and construction. Understanding this concept is essential for anyone involved in these fields, as it directly impacts the effectiveness and reliability of their work.

在工程和建筑领域，术语机械稳定化指的是通过机械手段增强结构和材料的稳定性。这一概念在土木工程、航空航天甚至汽车工业等多个应用中至关重要。机械稳定化背后的理念是通过采用加固、支撑和其他稳定装置等机械方法，提高结构的承载能力和整体性能。机械稳定化最常见的应用之一可以在建筑和桥梁的建设中看到。工程师通常利用钢梁或钢筋混凝土为这些结构提供额外的强度。通过结合这些机械元素，可以显著降低由于风或地震等外部力量导致的结构失效风险。这不仅确保了居住者的安全，还延长了结构的使用寿命。此外，机械稳定化在土壤力学领域也至关重要。在建造基础时，工程师必须考虑土壤的稳定性。例如，土钉技术是将钢杆插入地下以提供额外支持的做法，体现了如何有效应用机械稳定化来增强土壤稳定性。这一过程有助于防止滑坡和其他可能危及上方结构完整性的土壤相关问题。在航空航天行业，机械稳定化在确保飞机的安全性和性能方面发挥着关键作用。例如，飞机的机翼设计具有特定的机械特征，使其能够承受飞行中的湍流和其他气动力。这些组件的设计经过广泛的测试和模拟，以确保它们得到充分的稳定，这对航空旅行的整体安全至关重要。此外，在汽车工程中，机械稳定化用于增强车辆的稳定性和控制性。例如，汽车的悬挂系统旨在吸收冲击并保持轮胎与道路的接触。通过利用减震器和弹簧等各种机械组件，制造商可以确保车辆在转弯和不平坦的路面上保持稳定。这不仅改善了驾驶体验，还增强了乘客和行人的安全。总之，机械稳定化是各个工程学科中的一个基本概念，涉及使用机械方法来增强稳定性和性能。无论是在建筑物的建设、飞机的设计还是车辆的工程中，机械稳定化的原则在确保安全和耐久性方面发挥着至关重要的作用。随着技术的不断进步，用于机械稳定化的方法和技术可能会不断演变，带来更具创新性的工程和建筑解决方案。理解这一概念对于任何参与这些领域的人来说都是必不可少的，因为它直接影响到他们工作的有效性和可靠性。