delayed tripping

简明释义

延迟脱扣延迟跳闸

英英释义

例句

1.In high-voltage systems, delayed tripping can prevent nuisance trips during temporary faults.

在高压系统中，延迟跳闸可以防止在暂时故障期间的误跳闸。

2.The technician explained that delayed tripping is often used to protect sensitive machinery from sudden power interruptions.

技术员解释说，延迟跳闸通常用于保护敏感机械免受突然的电力中断。

3.During the test, the delayed tripping mechanism worked perfectly, allowing the system to stabilize before shutting down.

在测试过程中，延迟跳闸机制完美运行，使系统在关闭之前得以稳定。

4.The circuit breaker experienced delayed tripping due to a gradual increase in load, which allowed the equipment to operate longer than expected.

由于负载逐渐增加，电路断路器经历了延迟跳闸，这使得设备比预期运行更长时间。

5.Engineers designed the delayed tripping feature to enhance the reliability of the power distribution network.

工程师设计了延迟跳闸功能，以增强电力分配网络的可靠性。

作文

In the realm of electrical engineering and safety systems, the term delayed tripping refers to a specific mechanism that allows for a brief pause before a circuit breaker or protective device interrupts the flow of electricity. This feature is crucial in various applications, particularly in industrial settings where heavy machinery is involved. The primary purpose of delayed tripping is to prevent unnecessary interruptions caused by transient faults, which are temporary disturbances that may not indicate a serious problem. For instance, when a machine experiences a sudden surge of current due to a momentary overload, the delayed tripping mechanism can provide a grace period for the current to stabilize before taking action.The significance of delayed tripping becomes evident when considering the operational efficiency of equipment. In many cases, a quick disconnection from power could lead to costly downtime and potential damage to machinery. By incorporating a delayed tripping feature, operators can ensure that minor fluctuations do not trigger unnecessary shutdowns. This is particularly important in manufacturing environments where continuous operation is essential for productivity.Moreover, delayed tripping plays a vital role in protecting sensitive electronic devices that might be adversely affected by abrupt power cuts. For example, in data centers, servers require a stable power supply to maintain operations and protect valuable information. A sudden trip could result in data loss or corruption. Therefore, the implementation of delayed tripping systems helps to mitigate these risks, allowing for a more controlled response to electrical anomalies.In addition to its practical applications, understanding delayed tripping also highlights the importance of safety protocols in electrical systems. Engineers and technicians must carefully calibrate the delay settings to balance responsiveness with the need for stability. Too short a delay may still result in unwanted trips, while too long a delay could expose equipment to prolonged fault conditions. Thus, a thorough analysis of the specific environment and equipment is necessary to determine the optimal delay duration.Furthermore, delayed tripping mechanisms are not limited to just industrial applications; they are also found in residential electrical systems. Homeowners benefit from this technology through devices like smart circuit breakers, which can detect irregularities in power consumption and adjust their response accordingly. This innovation enhances home safety and energy efficiency, proving that the principles of delayed tripping are applicable across various sectors.In conclusion, the concept of delayed tripping is integral to modern electrical systems, providing a balance between safety and operational efficiency. By allowing a brief pause before interrupting power flow, this mechanism protects both equipment and data from unnecessary disruptions. As technology continues to evolve, the importance of understanding and implementing delayed tripping will only grow, ensuring that systems remain resilient in the face of electrical challenges.

在电气工程和安全系统的领域中，术语延迟跳闸指的是一种特定机制，它允许在断路器或保护装置中断电流之前进行短暂的暂停。这一特性在各种应用中至关重要，特别是在涉及重型机械的工业环境中。延迟跳闸的主要目的是防止由于瞬时故障引起的不必要中断，这些故障是暂时性的扰动，可能并不表明存在严重问题。例如，当机器由于瞬时过载而经历突然的电流激增时，延迟跳闸机制可以提供一个宽限期，以便电流稳定后再采取行动。当考虑到设备的操作效率时，延迟跳闸的重要性变得显而易见。在许多情况下，快速切断电源可能导致昂贵的停机时间和潜在的机械损坏。通过引入延迟跳闸特性，操作员可以确保轻微的波动不会触发不必要的停机。这在制造环境中尤其重要，因为持续的操作对于生产力至关重要。此外，延迟跳闸在保护可能受到突然断电影响的敏感电子设备方面也发挥着重要作用。例如，在数据中心，服务器需要稳定的电源供应以维持操作并保护宝贵的信息。突然的跳闸可能导致数据丢失或损坏。因此，实施延迟跳闸系统有助于减轻这些风险，从而实现对电气异常的更可控响应。除了其实际应用，理解延迟跳闸还突显了电气系统中安全协议的重要性。工程师和技术人员必须仔细校准延迟设置，以平衡响应性与稳定性之间的关系。延迟时间过短仍然可能导致不必要的跳闸，而延迟时间过长则可能使设备暴露于长期故障条件下。因此，对特定环境和设备进行全面分析是确定最佳延迟持续时间所必需的。此外，延迟跳闸机制不仅限于工业应用；它们在住宅电气系统中也可以找到。家庭用户通过智能断路器等设备受益于这一技术，这些设备可以检测电力消费中的不规则性并相应调整其响应。这一创新增强了家庭安全性和能源效率，证明了延迟跳闸的原则在各个领域的适用性。总之，延迟跳闸的概念是现代电气系统的一个重要组成部分，在安全性和操作效率之间提供了平衡。通过在中断电流流动之前允许短暂的暂停，这一机制保护了设备和数据免受不必要的干扰。随着技术的不断发展，理解和实施延迟跳闸的重要性只会增加，确保系统在电气挑战面前保持韧性。