break-before-make spring combination

简明释义

先后开合簧组

英英释义

例句

1.During the workshop, we learned how to implement a break-before-make spring combination in our designs.

在工作坊中，我们学习了如何在设计中实现先断后接的弹簧组合。

2.The engineer explained the importance of using a break-before-make spring combination in the circuit design to prevent short circuits.

工程师解释了在电路设计中使用先断后接的弹簧组合的重要性，以防止短路。

3.The technician adjusted the mechanism to ensure it utilized a break-before-make spring combination for better reliability.

技术员调整了机制，以确保它采用先断后接的弹簧组合以提高可靠性。

4.In robotics, a break-before-make spring combination is essential for ensuring that the arms do not collide during movement.

在机器人技术中，先断后接的弹簧组合对于确保臂部在移动时不会发生碰撞至关重要。

5.The safety manual recommended a break-before-make spring combination to avoid accidental activation of the machinery.

安全手册建议使用先断后接的弹簧组合以避免机器意外启动。

作文

In the field of engineering and design, the term break-before-make spring combination refers to a specific mechanism that ensures safety and efficiency in various applications. This concept is particularly relevant in systems where the release of energy must be carefully controlled to prevent accidents or malfunctions. To understand this phrase better, we can break it down into its components: 'break' and 'make'. The word 'break' implies the act of disengaging or releasing something. In the context of a spring mechanism, this means that the spring should first be released or broken from its tension before any new action can take place. This is crucial because if a spring is engaged while another mechanism is activated, it could lead to catastrophic failures or unintended consequences. For example, in automotive engineering, if a car's brake system does not properly disengage before the engine engages, it could result in a loss of control or even an accident. On the other hand, 'make' refers to the act of engaging or activating a mechanism. In a break-before-make spring combination, the engagement of a new mechanism only occurs after the previous one has been safely disengaged. This sequential operation is essential in ensuring that systems function smoothly without interference or risk of damage. One of the most common applications of the break-before-make spring combination can be found in the design of safety devices. For instance, in the deployment of airbags in vehicles, the system must first break the connection to the airbag sensor before the airbag itself can deploy. This ensures that the airbag only activates when necessary and under the right conditions, thereby protecting passengers from injury. Moreover, this principle is not limited to automotive applications; it can also be seen in various industrial machines, robotics, and even everyday devices like printers. For example, in a printer, the paper feed mechanism must disengage before the print head moves into position to avoid jamming or misalignment. By adhering to the break-before-make spring combination principle, manufacturers can create products that are not only reliable but also safe for users. Understanding the break-before-make spring combination is vital for engineers and designers who strive to create effective and secure mechanisms. It highlights the importance of sequence in mechanical operations and underscores the need for thorough testing and validation in engineering designs. As technology continues to evolve, the application of this principle will remain crucial in developing innovative solutions that prioritize safety and functionality. In conclusion, the break-before-make spring combination is a fundamental concept that plays a significant role in the design and operation of various mechanical systems. By ensuring that mechanisms are properly disengaged before new actions are taken, engineers can enhance the safety and reliability of their designs. This principle not only applies to complex machinery but also serves as a reminder of the importance of careful planning and execution in all areas of engineering. Through continued education and awareness of such concepts, we can contribute to a safer and more efficient technological future.

在工程和设计领域，术语断开后再连接弹簧组合指的是一种特定机制，确保在各种应用中的安全性和效率。这个概念在能量释放必须被仔细控制以防止事故或故障的系统中尤为相关。为了更好地理解这个短语，我们可以将其分解为两个部分：“断开”和“连接”。“断开”一词意味着解除或释放某物。在弹簧机制的上下文中，这意味着弹簧应首先从其张力中释放或断开，然后才能采取任何新的行动。这一点至关重要，因为如果在另一机制激活时弹簧仍处于连接状态，可能会导致灾难性的故障或意外后果。例如，在汽车工程中，如果汽车的刹车系统在发动机启动时没有正确解除，可能会导致失控甚至事故。另一方面，“连接”是指激活或启动机制的行为。在断开后再连接弹簧组合中，新的机制的激活仅在前一个机制安全解除之后发生。这种顺序操作对于确保系统平稳运行而不受干扰或损坏的风险至关重要。断开后再连接弹簧组合的一个常见应用可以在安全装置的设计中找到。例如，在车辆安全气囊的部署中，系统必须首先断开与安全气囊传感器的连接，然后安全气囊才能展开。这确保了安全气囊仅在必要时和在正确条件下激活，从而保护乘客免受伤害。此外，这一原理不仅限于汽车应用；它也可以在各种工业机器、机器人，甚至日常设备如打印机中看到。例如，在打印机中，纸张进给机制必须在打印头移动到位之前解除连接，以避免卡纸或对齐错误。通过遵循断开后再连接弹簧组合原理，制造商可以创造出不仅可靠而且对用户安全的产品。理解断开后再连接弹簧组合对那些努力创造有效和安全机制的工程师和设计师至关重要。它强调了机械操作中顺序的重要性，并强调了在工程设计中进行彻底测试和验证的必要性。随着技术的不断发展，这一原则的应用在开发优先考虑安全和功能的创新解决方案时将继续至关重要。总之，断开后再连接弹簧组合是一个基本概念，在各种机械系统的设计和操作中发挥着重要作用。通过确保机制在采取新行动之前得到妥善解除，工程师可以提高其设计的安全性和可靠性。这一原则不仅适用于复杂的机械，也提醒我们在所有工程领域中仔细规划和执行的重要性。通过持续的教育和对这些概念的认识，我们可以为一个更安全、更高效的技术未来做出贡献。