instantaneous voltage regulation characteristic

简明释义

瞬时电压调整特性曲线

英英释义

例句

1.Engineers tested the instantaneous voltage regulation characteristic of the transformer to prevent voltage drops during peak demand.

工程师测试了变压器的瞬时电压调节特性，以防止在高峰需求期间电压下降。

2.To enhance grid stability, the utility company focused on improving the instantaneous voltage regulation characteristic of their distribution network.

为了增强电网稳定性，公用事业公司专注于改善其配电网络的瞬时电压调节特性。

3.The simulation showed that the instantaneous voltage regulation characteristic of the circuit can handle sudden fluctuations effectively.

模拟显示，该电路的瞬时电压调节特性能够有效处理突发波动。

4.The new power supply unit features an improved instantaneous voltage regulation characteristic, ensuring stable output during load changes.

新的电源单元具有改进的瞬时电压调节特性，确保在负载变化时输出稳定。

5.A robust instantaneous voltage regulation characteristic is crucial for sensitive electronic devices that require consistent power.

强大的瞬时电压调节特性对于需要稳定电源的敏感电子设备至关重要。

作文

In the realm of electrical engineering, understanding various characteristics of voltage regulation is crucial for the design and operation of power systems. One important aspect that engineers focus on is the instantaneous voltage regulation characteristic. This term refers to the ability of a power system to maintain a stable voltage level in response to sudden changes in load or generation. The significance of this characteristic cannot be overstated, as it directly impacts the reliability and efficiency of electrical systems.To elaborate, the instantaneous voltage regulation characteristic essentially measures how quickly and effectively a power system can adjust its output voltage when there are fluctuations in demand. For instance, if a large industrial facility suddenly turns on several machines, the demand for electricity spikes instantaneously. A power system with a robust instantaneous voltage regulation characteristic will quickly detect this change and compensate by adjusting the voltage output to prevent any disruption in service.The importance of maintaining voltage stability is particularly evident during peak demand periods or when there are disturbances in the grid. If the voltage drops too low, it can lead to equipment malfunction or even failure, resulting in costly downtime and repairs. Conversely, if the voltage rises too high, it can damage sensitive electronic devices. Therefore, a power system's ability to exhibit a strong instantaneous voltage regulation characteristic is essential for ensuring the safety and longevity of electrical equipment.Moreover, advancements in technology have led to the development of various tools and methods to enhance the instantaneous voltage regulation characteristic of power systems. For example, the integration of smart grid technologies allows for real-time monitoring and automated adjustments to voltage levels. These innovations not only improve the responsiveness of power systems but also contribute to overall energy efficiency by reducing losses associated with voltage fluctuations.In addition to technological improvements, proper system design also plays a critical role in achieving optimal instantaneous voltage regulation characteristic. Engineers must consider factors such as transformer sizing, capacitor placement, and the use of voltage regulators when designing a power system. By carefully planning these elements, they can ensure that the system is capable of responding swiftly to changes in load without compromising voltage stability.Furthermore, regulatory standards often dictate the acceptable limits for voltage variations in order to protect consumers and equipment. As such, power system operators must continuously monitor their systems to ensure compliance with these standards while striving to enhance their instantaneous voltage regulation characteristic. This ongoing effort not only helps in maintaining system reliability but also builds consumer trust in the power supply.In conclusion, the instantaneous voltage regulation characteristic is a fundamental concept in the field of electrical engineering that underscores the importance of voltage stability in power systems. Its ability to respond to sudden changes in demand is vital for preventing equipment damage and ensuring reliable service. As technology continues to evolve, the methods for improving this characteristic will also advance, leading to more resilient and efficient electrical systems that can meet the demands of modern society. Understanding and enhancing the instantaneous voltage regulation characteristic will remain a priority for engineers aiming to create a sustainable energy future.

在电气工程领域，理解电压调节的各种特性对电力系统的设计和运行至关重要。工程师们关注的一个重要方面是瞬时电压调节特性。这个术语指的是电力系统在负载或发电突然变化时维持稳定电压水平的能力。这一特性的意义不容小觑，因为它直接影响电气系统的可靠性和效率。进一步来说，瞬时电压调节特性本质上衡量的是电力系统在需求波动时调整输出电压的速度和有效性。例如，如果一家大型工业设施突然开启几台机器，电力需求会瞬间激增。具有强大瞬时电压调节特性的电力系统将迅速检测到这一变化，并通过调整电压输出进行补偿，以防止服务中断。在高峰需求期间或电网发生扰动时，保持电压稳定的重要性尤为明显。如果电压过低，可能导致设备故障甚至损坏，从而造成昂贵的停机时间和维修费用。相反，如果电压过高，则可能损坏敏感的电子设备。因此，电力系统表现出强大的瞬时电压调节特性对于确保电气设备的安全和耐用性至关重要。此外，技术进步促进了增强电力系统瞬时电压调节特性的各种工具和方法的发展。例如，智能电网技术的整合使实时监测和自动调整电压水平成为可能。这些创新不仅提高了电力系统的响应能力，还通过减少与电压波动相关的损失来提高整体能效。除了技术改进，适当的系统设计在实现最佳瞬时电压调节特性方面也起着至关重要的作用。工程师们在设计电力系统时必须考虑变压器尺寸、电容器位置和电压调节器的使用等因素。通过仔细规划这些元素，他们可以确保系统能够迅速响应负载变化，而不妨碍电压稳定性。此外，监管标准通常规定了电压变化的可接受范围，以保护消费者和设备。因此，电力系统操作员必须持续监测其系统，以确保遵守这些标准，同时努力增强其瞬时电压调节特性。这一持续努力不仅有助于维持系统的可靠性，还建立了消费者对电力供应的信任。总之，瞬时电压调节特性是电气工程领域的一个基本概念，强调了电力系统中电压稳定性的重要性。其对需求突变的快速响应能力对于防止设备损坏和确保可靠服务至关重要。随着技术的不断发展，改善这一特性的方法也将不断进步，从而导致更具韧性和效率的电力系统，能够满足现代社会的需求。理解和增强瞬时电压调节特性将始终是工程师们致力于创造可持续能源未来的优先事项。