minimum starting revolution

简明释义

最低起动转数

英英释义

例句

1.The engine requires a minimum starting revolution to ignite the fuel properly.

发动机需要达到最小启动转速才能正确点燃燃料。

2.In order for the fan to operate efficiently, it must reach its minimum starting revolution quickly.

为了让风扇高效运行，它必须迅速达到其最小启动转速。

3.If the minimum starting revolution is not met, the machinery may stall.

如果未达到最小启动转速，机器可能会停滞不前。

4.The manufacturer specifies a minimum starting revolution for the motor to ensure safety.

制造商规定了电动机的最小启动转速以确保安全。

5.Technicians often test the minimum starting revolution during routine maintenance checks.

技术人员在例行维护检查中通常会测试最小启动转速。

作文

In the world of engineering and mechanics, understanding the concept of minimum starting revolution is crucial for optimizing the performance of various machines. The term refers to the lowest speed at which a motor or engine can start operating efficiently. This concept is particularly significant in applications where precision and reliability are paramount. For instance, in electric motors, the minimum starting revolution determines the threshold at which the motor can overcome inertia and begin its rotation. If the motor does not reach this speed, it may stall, leading to potential damage and decreased efficiency.The significance of the minimum starting revolution extends beyond just motors; it is also applicable in the context of internal combustion engines. These engines require a certain level of revolutions per minute (RPM) to initiate combustion and maintain operation. Understanding this threshold is essential for engineers when designing vehicles and machinery that rely on these engines. If a vehicle's engine cannot achieve the minimum starting revolution, it may fail to start, causing inconvenience and potentially leading to costly repairs.Moreover, the minimum starting revolution plays a vital role in the field of robotics. Robots often utilize electric motors for movement, and their effectiveness can be significantly affected by this parameter. Engineers must ensure that the motors used in robotic systems can reach the minimum starting revolution required for the tasks they are designed to perform. Failure to do so may result in robots that are unable to execute their functions properly, leading to inefficiencies and operational failures.In practical applications, understanding the minimum starting revolution can also help in energy conservation. By ensuring that machines operate within their optimal speed ranges, businesses can reduce energy consumption and lower operational costs. For example, in manufacturing processes, machines that operate below their minimum starting revolution may consume more energy than necessary, as they struggle to maintain motion. Therefore, by monitoring and adjusting machine speeds, companies can enhance productivity while minimizing waste.Furthermore, the minimum starting revolution is critical in safety considerations. In many industrial settings, equipment that does not meet this threshold can pose serious risks. For instance, a conveyor belt system that fails to start due to insufficient revolutions can lead to material jams, which may cause accidents or injuries. Hence, understanding this concept not only aids in operational efficiency but also ensures a safer working environment.In conclusion, the minimum starting revolution is a fundamental concept that impacts various fields, including engineering, robotics, and manufacturing. By grasping this idea, professionals can optimize machine performance, enhance energy efficiency, and improve safety measures. As technology continues to advance, the importance of understanding such parameters will only grow, making it essential for engineers and technicians to have a thorough comprehension of the minimum starting revolution and its implications in their respective fields.

在工程和机械的世界中，理解“最低起始转速”的概念对于优化各种机器的性能至关重要。这个术语指的是电动机或引擎能够有效启动的最低速度。这个概念在需要精确和可靠性的应用中尤为重要。例如，在电动机中，最低起始转速决定了电动机克服惯性并开始旋转的阈值。如果电动机未能达到这个速度，它可能会停转，从而导致潜在的损坏和效率降低。最低起始转速的重要性不仅限于电动机；它在内燃机的背景下同样适用。这些引擎需要一定的转速（每分钟转数）来启动燃烧并保持运行。理解这一阈值对于工程师在设计依赖这些引擎的车辆和机器时至关重要。如果一辆车的引擎无法达到最低起始转速，它可能无法启动，造成不便，并可能导致昂贵的维修费用。此外，最低起始转速在机器人领域也发挥着重要作用。机器人通常利用电动机进行运动，而这一参数对其有效性有显著影响。工程师必须确保用于机器人系统的电动机能够达到执行所设计任务所需的最低起始转速。如果未能做到这一点，可能导致机器人无法正常执行其功能，从而导致效率低下和操作失败。在实际应用中，理解最低起始转速还有助于节能。通过确保机器在其最佳速度范围内运行，企业可以减少能源消耗并降低运营成本。例如，在制造过程中，低于其最低起始转速运行的机器可能会消耗更多的能源，因为它们努力维持运动。因此，通过监控和调整机器速度，公司可以提高生产力，同时最小化浪费。此外，最低起始转速在安全考虑中也至关重要。在许多工业环境中，未达到这一阈值的设备可能会带来严重风险。例如，由于转速不足而无法启动的输送带系统可能导致物料堵塞，从而可能引发事故或伤害。因此，理解这一概念不仅有助于操作效率，还能确保更安全的工作环境。总之，最低起始转速是一个基本概念，影响着工程、机器人和制造等多个领域。通过掌握这一理念，专业人士可以优化机器性能，提高能源效率，并改善安全措施。随着技术的不断进步，理解此类参数的重要性只会增加，因此工程师和技术人员必须深入理解最低起始转速及其在各自领域中的影响。