machine dynamics
简明释义
机械动力学
英英释义
Machine dynamics refers to the study of the motion and behavior of machines and mechanical systems, including the forces and torques that cause movement. | 机器动力学是研究机器和机械系统的运动和行为,包括导致运动的力和扭矩。 |
例句
1.Engineers often use simulations to analyze machine dynamics 机器动态学 before physical prototyping.
工程师通常在物理原型制作之前使用模拟来分析机器动态学。
2.Courses on machine dynamics 机器动态学 are essential for mechanical engineering students.
关于机器动态学的课程对于机械工程专业的学生至关重要。
3.The study of machine dynamics 机器动态学 helps in predicting the behavior of machinery under different loads.
对机器动态学的研究有助于预测机器在不同负载下的行为。
4.In robotics, machine dynamics 机器动态学 plays a key role in motion planning and control.
在机器人技术中,机器动态学在运动规划和控制中发挥着关键作用。
5.Understanding machine dynamics 机器动态学 is crucial for designing efficient mechanical systems.
理解机器动态学对于设计高效的机械系统至关重要。
作文
Machine dynamics is a crucial field of study within mechanical engineering that focuses on the behavior of machines under various forces and motions. Understanding machine dynamics (机器动力学) allows engineers to design more efficient and reliable machines. The principles of machine dynamics (机器动力学) encompass the analysis of moving parts, the forces acting upon them, and how these elements interact over time.In the world of engineering, machines are everywhere—from simple household appliances to complex industrial machinery. Each machine operates based on specific principles of physics and mechanics. By studying machine dynamics (机器动力学), engineers can predict how a machine will behave when it is in motion, which is essential for ensuring safety and functionality.One of the core concepts in machine dynamics (机器动力学) is the relationship between force, mass, and acceleration, as described by Newton's second law of motion. This principle helps engineers understand how different forces affect a machine's components during operation. For example, when designing an engine, engineers must consider the impact of combustion forces on the movement of pistons and other parts. Without a solid grasp of machine dynamics (机器动力学), it would be challenging to create an engine that operates smoothly and efficiently.Another important aspect of machine dynamics (机器动力学) is vibration analysis. Many machines experience vibrations during operation, which can lead to wear and tear or even catastrophic failure if not managed properly. Engineers use machine dynamics (机器动力学) principles to analyze these vibrations and develop solutions to minimize their effects. This could involve redesigning parts, adding dampers, or changing operational procedures to ensure that the machine remains stable and functional over time.Moreover, the study of machine dynamics (机器动力学) also includes kinematics, which is the study of motion without considering the forces that cause it. Kinematic analysis helps engineers visualize how different components of a machine move relative to one another. This understanding is vital when creating animations or simulations of machine operations, allowing engineers to identify potential issues before physical prototypes are built.The application of machine dynamics (机器动力学) extends beyond traditional mechanical engineering. In fields like robotics, aerospace, and automotive engineering, understanding the dynamics of machines is essential for innovation. For instance, the development of autonomous vehicles relies heavily on machine dynamics (机器动力学) to ensure that all moving parts interact seamlessly, providing a safe and efficient driving experience.In conclusion, machine dynamics (机器动力学) is a fundamental aspect of engineering that plays a vital role in the design and functionality of machines. From analyzing forces and vibrations to understanding kinematics, the principles of machine dynamics (机器动力学) are integral to creating reliable and efficient machines across various industries. As technology continues to advance, the importance of mastering machine dynamics (机器动力学) will only grow, paving the way for innovations that enhance our daily lives.
机器动力学是机械工程中的一个关键研究领域,专注于机器在各种力量和运动下的行为。理解机器动力学(machine dynamics)使工程师能够设计出更高效、更可靠的机器。机器动力学(machine dynamics)的原理包括对运动部件的分析、作用于它们的力量以及这些元素随时间的相互作用。在工程的世界里,机器无处不在——从简单的家用电器到复杂的工业机械。每台机器的操作都基于特定的物理和力学原理。通过研究机器动力学(machine dynamics),工程师可以预测机器在运动时的行为,这对于确保安全性和功能性至关重要。机器动力学(machine dynamics)中的核心概念之一是力、质量和加速度之间的关系,这由牛顿第二运动定律描述。这个原理帮助工程师理解不同的力量如何影响机器部件在运行过程中的表现。例如,在设计发动机时,工程师必须考虑燃烧力对活塞和其他部件运动的影响。如果没有对机器动力学(machine dynamics)的深刻理解,创造出平稳高效运作的发动机将会非常困难。机器动力学(machine dynamics)的另一个重要方面是振动分析。许多机器在运行过程中都会经历振动,如果不加以管理,这可能导致磨损甚至灾难性的故障。工程师利用机器动力学(machine dynamics)原理来分析这些振动,并制定解决方案以最小化其影响。这可能涉及重新设计部件、添加阻尼器或改变操作程序,以确保机器在长时间运行中保持稳定和功能正常。此外,机器动力学(machine dynamics)的研究还包括运动学,即在不考虑导致运动的力量的情况下研究运动。运动学分析帮助工程师可视化机器不同部件相对彼此的运动。这种理解在创建机器操作的动画或模拟时至关重要,使工程师能够在构建物理原型之前识别潜在问题。机器动力学(machine dynamics)的应用不仅限于传统的机械工程。在机器人技术、航空航天和汽车工程等领域,理解机器的动力学对于创新至关重要。例如,自动驾驶汽车的开发在很大程度上依赖于机器动力学(machine dynamics),以确保所有运动部件无缝互动,提供安全高效的驾驶体验。总之,机器动力学(machine dynamics)是工程的一个基本方面,在机器的设计和功能中发挥着重要作用。从分析力量和振动到理解运动学,机器动力学(machine dynamics)的原理对于在各个行业创造可靠和高效的机器是不可或缺的。随着技术的不断进步,掌握机器动力学(machine dynamics)的重要性只会增加,为增强我们日常生活的创新铺平道路。
相关单词
