disruptive voltage

简明释义

哗电压

英英释义

例句

1.The circuit experienced a spike in disruptive voltage, causing a temporary shutdown of the system.

电路经历了一个干扰电压的尖峰，导致系统暂时关闭。

2.The generator was affected by disruptive voltage, resulting in fluctuating power output.

发电机受到干扰电压的影响，导致输出电力波动。

3.To prevent disruptive voltage, the installation included surge protectors.

为了防止干扰电压，安装中包括了浪涌保护器。

4.A sudden change in load can create disruptive voltage that damages sensitive components.

负载的突然变化可能会产生干扰电压，损坏敏感组件。

5.Engineers must design equipment to withstand disruptive voltage during electrical storms.

工程师必须设计设备以承受电气风暴中的干扰电压。

作文

In the world of electrical engineering, the concept of disruptive voltage plays a critical role in understanding the behavior of electrical systems under various conditions. Disruptive voltage refers to a voltage level that is capable of causing significant disturbances in an electrical circuit or system. This can lead to unexpected behaviors such as equipment malfunction, data corruption, or even catastrophic failures. Understanding the implications of disruptive voltage is essential for engineers and technicians who design and maintain electrical systems.One of the primary causes of disruptive voltage is lightning strikes. When lightning hits a power line, it generates a surge of electrical energy that can drastically increase the voltage in the system. This sudden spike can damage transformers, circuit breakers, and other critical components, leading to outages and costly repairs. Therefore, implementing protective measures, such as surge arresters, is vital in mitigating the effects of disruptive voltage caused by natural phenomena.Another source of disruptive voltage is switching operations within the electrical grid. When large loads are turned on or off, the abrupt change in current can create voltage transients that propagate through the system. These transients can interfere with sensitive electronic devices, causing them to malfunction or even fail. Engineers must carefully analyze these switching events to ensure that they do not produce disruptive voltage levels that exceed the tolerances of the equipment involved.In addition to natural and operational causes, disruptive voltage can also arise from human error. For instance, improper grounding techniques during installation can lead to unintentional voltage differentials that disrupt normal operations. It is crucial for electrical professionals to adhere to strict safety protocols and guidelines to avoid introducing disruptive voltage into their systems.The consequences of disruptive voltage extend beyond individual devices; they can affect entire networks. A single point of failure due to excessive voltage can cascade through interconnected systems, leading to widespread outages. This effect is particularly concerning in critical infrastructures such as hospitals, data centers, and transportation systems, where reliability is paramount. As such, engineers must consider disruptive voltage when designing redundant systems and backup procedures to enhance resilience against voltage spikes.To address the challenges posed by disruptive voltage, ongoing research and development in the field of electrical engineering are essential. New technologies, such as advanced monitoring systems and smart grid solutions, are being developed to detect and respond to voltage anomalies in real-time. By leveraging these innovations, engineers can better manage the risks associated with disruptive voltage and ensure the stability of electrical systems.In conclusion, disruptive voltage is a term that encapsulates the potential dangers associated with voltage surges in electrical systems. From natural occurrences like lightning to operational challenges and human errors, the sources of disruptive voltage are diverse and complex. Understanding these dynamics is crucial for engineers tasked with designing safe and reliable electrical infrastructure. As technology continues to evolve, so too will our strategies for mitigating the risks posed by disruptive voltage, ensuring that our electrical systems remain robust and resilient in the face of challenges.

在电气工程的世界中，disruptive voltage（干扰电压）这一概念在理解电气系统在各种条件下的行为中发挥着关键作用。disruptive voltage指的是能够在电路或系统中引起显著干扰的电压水平。这可能导致意外行为，如设备故障、数据损坏，甚至灾难性故障。理解disruptive voltage的影响对于设计和维护电气系统的工程师和技术人员至关重要。disruptive voltage的主要原因之一是雷击。当雷电击中电力线时，会产生一股电能涌流，极大地增加系统中的电压。这种突然的电压激增可能会损坏变压器、断路器和其他关键组件，导致停电和昂贵的维修。因此，实施保护措施，如浪涌保护器，对于减轻自然现象造成的disruptive voltage影响是至关重要的。另一个导致disruptive voltage的来源是电网内的切换操作。当大型负载被打开或关闭时，电流的突然变化会产生电压瞬变，这些瞬变可以传播到系统中，干扰敏感的电子设备，导致其故障甚至失效。工程师必须仔细分析这些切换事件，以确保它们不会产生超出设备耐受范围的disruptive voltage水平。除了自然和操作原因，disruptive voltage还可能由于人为错误而产生。例如，在安装过程中不当的接地技术可能导致无意的电压差，从而破坏正常操作。电气专业人员必须遵循严格的安全协议和指南，以避免在其系统中引入disruptive voltage。disruptive voltage的后果不仅限于单个设备；它们可能影响整个网络。由于过高电压导致的单点故障可能会在互联系统中级联，引发广泛的停电。这种影响在医院、数据中心和交通系统等关键基础设施中尤为令人担忧，因为这些地方的可靠性至关重要。因此，工程师在设计冗余系统和备份程序时，必须考虑到disruptive voltage，以增强对电压激增的抗干扰能力。为了解决disruptive voltage带来的挑战，电气工程领域的持续研究和开发至关重要。新的技术，如先进的监测系统和智能电网解决方案，正在开发中，以实时检测和响应电压异常。通过利用这些创新，工程师可以更好地管理与disruptive voltage相关的风险，确保电气系统的稳定性。总之，disruptive voltage是一个概括了电气系统中电压激增相关潜在危险的术语。从雷电等自然现象到操作挑战和人为错误，disruptive voltage的来源多种多样且复杂。理解这些动态对于负责设计安全可靠电气基础设施的工程师至关重要。随着技术的不断发展，我们应对disruptive voltage所带来的风险的策略也将不断演变，确保我们的电气系统在面临挑战时保持强大和韧性。