gear rolling

简明释义

齿轮滚轧

英英释义

例句

1.The team is focused on getting the project moving and has started the gear rolling.

团队专注于推动项目进展，已经开始了启动。

2.Once we finalize the budget, we can really get the gear rolling on this initiative.

一旦我们确定预算，就可以真正开始这个计划的启动。

3.To ensure success, we must keep the gear rolling throughout the development phase.

为了确保成功，我们必须在开发阶段保持持续推进。

4.After the meeting, we will need to start gear rolling to meet the deadlines.

会议结束后，我们需要开始启动以满足截止日期。

5.The marketing department is excited to see the gear rolling on the new campaign.

市场部门对新活动的启动感到兴奋。

作文

In the world of mechanics and engineering, understanding the principles of motion is crucial. One such principle that plays a significant role in various machines and vehicles is the concept of gear rolling. gear rolling refers to the process where gears engage and rotate smoothly, transferring motion and power from one part of a machine to another. This process is essential in ensuring that machines operate efficiently and effectively. Without proper gear rolling, mechanical systems can experience increased friction, wear, and ultimately failure. The importance of gear rolling can be observed in everyday applications, from automobiles to industrial machinery. For instance, in a car's transmission system, gears must roll smoothly to allow for seamless shifting between different speeds. If the gears do not engage correctly, it can lead to a rough ride, decreased fuel efficiency, and potential damage to the transmission. Therefore, engineers spend considerable time designing gear systems that promote optimal gear rolling. Moreover, the concept of gear rolling extends beyond just the physical interaction of gears. It also encompasses the design and material selection for gears. Engineers must consider factors such as the gear's shape, size, and the materials used in its construction to ensure that gear rolling occurs without excessive wear or failure. For example, using high-strength steel or advanced composites can enhance the durability of gears, allowing them to withstand the stresses of operation while maintaining smooth motion. In addition to mechanical applications, gear rolling has implications in robotics and automation. In robotic systems, precise movement is essential for tasks ranging from assembly to surgical procedures. The integration of gears that facilitate gear rolling allows robots to perform complex movements with accuracy and reliability. As technology advances, the demand for more sophisticated gear systems continues to grow, pushing engineers to innovate and improve gear rolling techniques. Furthermore, understanding the dynamics of gear rolling can lead to advancements in energy efficiency. By optimizing gear designs and minimizing friction, machines can operate with less energy consumption, contributing to sustainability efforts. For example, in wind turbines, efficient gear rolling mechanisms are vital for converting wind energy into electrical energy effectively. Engineers are continuously researching ways to enhance gear rolling to maximize energy output while reducing operational costs. In conclusion, gear rolling is a fundamental concept in mechanics that impacts a wide range of industries and applications. From automotive engineering to robotics, the ability of gears to roll smoothly and efficiently is critical for the performance and longevity of machines. As technology evolves, the study and application of gear rolling will remain a key focus for engineers seeking to improve mechanical systems and drive innovation in various fields. Understanding and mastering gear rolling is essential for anyone involved in engineering and design, as it lays the foundation for creating reliable and efficient machines that meet the demands of modern society.

在机械和工程的世界中，理解运动原理至关重要。其中一个在各种机器和车辆中发挥重要作用的原理是齿轮滚动的概念。齿轮滚动是指齿轮相互啮合并平稳旋转的过程，将运动和动力从机器的一部分传递到另一部分。这个过程对确保机器高效、有效地运行至关重要。如果没有适当的齿轮滚动，机械系统可能会经历增加的摩擦、磨损，最终导致故障。齿轮滚动的重要性可以在日常应用中观察到，从汽车到工业机械。例如，在汽车的传动系统中，齿轮必须平稳地滚动，以便在不同速度之间无缝切换。如果齿轮未能正确啮合，可能会导致行驶不顺畅、燃油效率下降以及传动系统的潜在损坏。因此，工程师花费大量时间设计促进最佳齿轮滚动的齿轮系统。此外，齿轮滚动的概念不仅限于齿轮的物理互动。它还包括齿轮的设计和材料选择。工程师必须考虑齿轮的形状、尺寸以及其构造所用材料等因素，以确保齿轮滚动不会过度磨损或失效。例如，使用高强度钢或先进复合材料可以增强齿轮的耐用性，使其能够承受操作中的压力，同时保持平稳运动。除了机械应用，齿轮滚动在机器人和自动化中也有重要意义。在机器人系统中，精确的运动对于从组装到外科手术等任务至关重要。促进齿轮滚动的齿轮集成使机器人能够以准确和可靠的方式执行复杂的运动。随着技术的进步，对更复杂的齿轮系统的需求不断增长，推动工程师创新和改善齿轮滚动技术。此外，理解齿轮滚动的动态特性可以促进能源效率的提升。通过优化齿轮设计和最小化摩擦，机器可以以更少的能耗运行，为可持续发展努力做出贡献。例如，在风力涡轮机中，高效的齿轮滚动机制对于有效地将风能转化为电能至关重要。工程师们正在不断研究如何增强齿轮滚动，以最大化能源输出，同时降低运营成本。总之，齿轮滚动是机械学中的一个基本概念，影响着广泛的行业和应用。从汽车工程到机器人，齿轮平稳高效地滚动的能力对机器的性能和寿命至关重要。随着技术的发展，齿轮滚动的研究和应用将继续成为工程师关注的重点，推动各个领域的创新。理解和掌握齿轮滚动对于任何参与工程和设计的人来说都是必不可少的，因为它为创造满足现代社会需求的可靠高效的机器奠定了基础。