voltage of system

简明释义

线路电压

英英释义

例句

1.A sudden drop in the voltage of system can indicate a fault in the circuit.

系统中电压的突然下降可能表明电路存在故障。

2.The technician adjusted the settings to stabilize the voltage of system.

技术员调整设置以稳定系统电压。

3.In renewable energy systems, the voltage of system must be regulated to optimize performance.

在可再生能源系统中，必须调节系统电压以优化性能。

4.Monitoring the voltage of system is crucial for preventing equipment damage.

监测系统电压对于防止设备损坏至关重要。

5.The engineer measured the voltage of system to ensure it was within safe limits.

工程师测量了系统电压以确保其在安全范围内。

作文

In the field of electrical engineering, understanding the concept of voltage of system is paramount. The voltage of system refers to the electric potential difference within a particular electrical system. It is a crucial parameter that affects how electrical devices operate and interact with each other. Essentially, the voltage of system determines the amount of energy available to drive current through the circuit. When designing electrical systems, engineers must consider the voltage of system carefully. For example, residential electrical systems typically operate at 120 or 240 volts, while industrial systems may use much higher voltages. This difference in voltage of system can significantly impact the type of equipment used, the safety measures required, and the overall efficiency of the system. Moreover, the voltage of system plays an essential role in power distribution. High-voltage transmission lines are employed to transport electricity over long distances with minimal energy loss. By stepping up the voltage of system at the generation point and stepping it down at the consumption point, utilities can ensure that electricity remains efficient and cost-effective. Another important aspect of the voltage of system is its relationship with current and resistance, as described by Ohm's Law. According to this law, the current flowing through a conductor between two points is directly proportional to the voltage across the two points and inversely proportional to the resistance. Therefore, understanding the voltage of system allows engineers to predict how changes in resistance will impact current flow, aiding in the design and troubleshooting of electrical circuits. In modern applications, the voltage of system is also significant in renewable energy systems, such as solar panels and wind turbines. These systems often require inverters to convert the direct current (DC) generated into alternating current (AC) that matches the voltage of system used in homes and businesses. This conversion process must be precisely managed to ensure that the voltage of system is stable and compatible with existing electrical infrastructure. Furthermore, safety is a critical consideration when dealing with the voltage of system. High voltages can pose serious risks, including electrical shock and fire hazards. Therefore, proper insulation, protective equipment, and adherence to safety standards are essential when working with systems that operate at high voltages. Engineers must be trained to understand these risks and implement measures to mitigate them effectively. In conclusion, the voltage of system is a fundamental concept in electrical engineering that influences the design, operation, and safety of electrical systems. From residential homes to large industrial plants, the voltage of system dictates how electricity is generated, transmitted, and consumed. A thorough understanding of this concept is vital for anyone involved in the field of electrical engineering, as it impacts everything from efficiency to safety.

在电气工程领域，理解“系统电压”的概念至关重要。“系统电压”是指特定电气系统内的电位差。这是一个关键参数，会影响电气设备的运行和相互作用。简单来说，“系统电压”决定了驱动电流通过电路的能量量。在设计电气系统时，工程师必须仔细考虑“系统电压”。例如，住宅电气系统通常在120或240伏特下运行，而工业系统可能使用更高的电压。这种“系统电压”的差异会显著影响所使用设备的类型、所需的安全措施及系统的整体效率。此外，“系统电压”在电力分配中也扮演着重要角色。高电压输电线路被用于在长距离传输电力时最大限度地减少能量损失。通过在发电点提高“系统电压”，并在消费点降低它，公用事业公司可以确保电力保持高效且具有成本效益。“系统电压”的另一个重要方面是它与电流和电阻之间的关系，如欧姆定律所描述的。根据这一法则，两个点之间导体中流动的电流与两点之间的电压成正比，与电阻成反比。因此，理解“系统电压”使工程师能够预测电阻变化将如何影响电流流动，从而帮助设计和排除电气电路的故障。在现代应用中，“系统电压”在可再生能源系统（如太阳能电池板和风力涡轮机）中也具有重要意义。这些系统通常需要逆变器将产生的直流电（DC）转换为与家庭和企业使用的交流电（AC）相匹配的“系统电压”。这一转换过程必须得到精确管理，以确保“系统电压”稳定，并与现有电气基础设施兼容。此外，在处理“系统电压”时，安全性也是一个关键考虑因素。高电压可能带来严重风险，包括电击和火灾危险。因此，在处理高电压运行的系统时，适当的绝缘、保护设备和遵守安全标准是必不可少的。工程师必须接受培训，以理解这些风险并有效实施减轻措施。总之，“系统电压”是电气工程中的一个基本概念，影响电气系统的设计、运行和安全。从住宅到大型工业厂房，“系统电压”决定了电力的生成、传输和消费。对这一概念的透彻理解对于任何参与电气工程领域的人来说都是至关重要的，因为它影响着从效率到安全的方方面面。