applied mechanics

简明释义

应用力学

英英释义

例句

1.The principles of applied mechanics can be seen in the way vehicles are constructed.

在车辆的构造中可以看到应用力学的原理。

2.The study of applied mechanics is essential for engineers who design bridges.

对工程师来说，学习应用力学对于设计桥梁至关重要。

3.A solid grasp of applied mechanics helps architects create stable structures.

对应用力学的扎实掌握帮助建筑师创造稳定的结构。

4.In our physics class, we often discuss applied mechanics to understand real-world problems.

在我们的物理课上，我们经常讨论应用力学以理解现实世界的问题。

5.We applied applied mechanics concepts to solve the problem of motion in our project.

我们在项目中应用了应用力学的概念来解决运动问题。

作文

Applied mechanics is a branch of physical science that deals with the practical application of mechanical principles. It encompasses various fields such as engineering, physics, and material science. The primary goal of applied mechanics (应用力学) is to solve real-world problems by applying theoretical concepts and mathematical models. This discipline plays a crucial role in the design and analysis of structures, machines, and systems, making it indispensable in modern technology. One of the fundamental aspects of applied mechanics (应用力学) is its focus on the behavior of materials under different forces. Engineers and scientists utilize the principles of mechanics to predict how materials will respond to loads, whether they are static or dynamic. For example, when designing a bridge, engineers must consider factors such as tension, compression, and shear forces to ensure that the structure can support the weight of vehicles and withstand environmental conditions. Moreover, applied mechanics (应用力学) also involves the study of motion and the forces that cause objects to move. Kinematics and dynamics are two key areas within this field. Kinematics focuses on describing motion without considering the forces that cause it, while dynamics examines the relationship between motion and the forces acting on an object. This understanding is vital in various applications, including automotive engineering, aerospace design, and robotics. In addition to static and dynamic analysis, applied mechanics (应用力学) also covers fluid mechanics, which studies the behavior of fluids (liquids and gases) in motion and at rest. Fluid mechanics is essential in numerous industries, from designing efficient transportation systems to understanding natural phenomena like weather patterns and ocean currents. Engineers apply these principles to optimize designs for pumps, turbines, and even aircraft, ensuring they operate efficiently and safely. The interdisciplinary nature of applied mechanics (应用力学) allows for collaboration among various fields. For instance, civil engineers work closely with mechanical engineers to develop infrastructure projects that require a deep understanding of both materials and mechanics. Similarly, biomedical engineers apply the principles of mechanics to create prosthetics and medical devices that mimic the natural movement of the human body. Furthermore, advancements in technology have significantly impacted the field of applied mechanics (应用力学). Computer simulations and modeling tools enable engineers to analyze complex systems more accurately and efficiently than ever before. Finite element analysis (FEA) and computational fluid dynamics (CFD) are examples of techniques that allow for detailed examination of how structures and fluids behave under various conditions. These tools not only save time and resources but also enhance the safety and reliability of engineering designs. In conclusion, applied mechanics (应用力学) is a vital discipline that bridges the gap between theoretical concepts and practical applications. Its influence spans across multiple industries, contributing to the development of innovative technologies and solutions. By understanding the principles of mechanics and their applications, engineers can tackle complex challenges and improve the quality of life for people around the world. As technology continues to evolve, the importance of applied mechanics (应用力学) will only grow, making it an essential area of study for future generations of engineers and scientists.

应用力学是物理科学的一个分支，涉及机械原理的实际应用。它涵盖了工程、物理学和材料科学等多个领域。应用力学（应用力学）的主要目标是通过应用理论概念和数学模型来解决现实世界中的问题。这一学科在结构、机器和系统的设计与分析中发挥着至关重要的作用，使其在现代技术中不可或缺。应用力学（应用力学）的一个基本方面是关注材料在不同力作用下的行为。工程师和科学家利用力学原理预测材料在静态或动态负载下的反应。例如，在设计桥梁时，工程师必须考虑拉伸、压缩和剪切力等因素，以确保结构能承受车辆的重量并抵御环境条件。此外，应用力学（应用力学）还涉及运动的研究以及导致物体运动的力。运动学和动力学是这一领域的两个关键领域。运动学专注于描述运动而不考虑导致运动的力，而动力学则研究运动与作用在物体上的力之间的关系。这种理解在汽车工程、航空航天设计和机器人技术等各种应用中至关重要。除了静态和动态分析外，应用力学（应用力学）还涵盖流体力学，研究流体（液体和气体）在运动和静止状态下的行为。流体力学在众多行业中至关重要，从设计高效的运输系统到理解天气模式和海洋洋流等自然现象。工程师应用这些原理来优化泵、涡轮机甚至飞机的设计，确保它们高效安全地运行。应用力学（应用力学）的跨学科特性使得各个领域之间能够进行合作。例如，土木工程师与机械工程师紧密合作，开发需要深入理解材料和力学的基础设施项目。同样，生物医学工程师应用力学原理来创建模仿人类身体自然运动的假肢和医疗设备。此外，技术的进步对应用力学（应用力学）领域产生了重大影响。计算机模拟和建模工具使工程师能够比以往更准确、高效地分析复杂系统。有限元分析（FEA）和计算流体动力学（CFD）是允许详细检查结构和流体在各种条件下行为的技术示例。这些工具不仅节省了时间和资源，还增强了工程设计的安全性和可靠性。总之，应用力学（应用力学）是一个重要的学科，弥合了理论概念与实际应用之间的鸿沟。它的影响跨越多个行业，为创新技术和解决方案的发展做出了贡献。通过理解力学原理及其应用，工程师可以应对复杂的挑战，提高全球人民的生活质量。随着技术的不断发展，应用力学（应用力学）的重要性只会增加，使其成为未来工程师和科学家学习的必修领域。