two bus-bar regulation

简明释义

双汇流条调整

英英释义

例句

1.The new power distribution system implements two bus-bar regulation to enhance reliability.

新的电力分配系统实施了双母线调节以增强可靠性。

2.Implementing two bus-bar regulation can significantly reduce downtime in power systems.

实施双母线调节可以显著减少电力系统的停机时间。

3.In our latest project, we focused on two bus-bar regulation for better load management.

在我们最新的项目中，我们专注于双母线调节以更好地管理负载。

4.The engineers discussed the advantages of two bus-bar regulation during the meeting.

工程师们在会议上讨论了双母线调节的优点。

5.The two bus-bar regulation technique is essential for ensuring continuous power supply.

为了确保持续供电，双母线调节技术至关重要。

作文

In the realm of electrical engineering, the efficiency and reliability of power distribution systems are paramount. One of the methods utilized to enhance these aspects is the concept of two bus-bar regulation. This technique involves the use of two bus-bars in a power system to manage the flow of electricity more effectively. By employing two bus-bar regulation, engineers can ensure that power is distributed evenly, reducing the risk of overloads and enhancing the stability of the electrical grid.To understand the significance of two bus-bar regulation, it is essential to grasp what a bus-bar is. A bus-bar is a conductive material, typically made of copper or aluminum, that serves as a central point for the distribution of electrical power. It connects multiple circuits and allows for the efficient transfer of electricity from one point to another. In a typical power distribution setup, a single bus-bar might be used; however, this can lead to vulnerabilities, especially during maintenance or in the event of a fault.The implementation of two bus-bar regulation addresses these vulnerabilities by providing redundancy. With two bus-bars, one can serve as a backup for the other. This means that if one bus-bar needs to be taken offline for maintenance or experiences a failure, the other can continue to operate, ensuring that power supply remains uninterrupted. This redundancy is crucial for critical infrastructure, such as hospitals and data centers, where power outages can have dire consequences.Moreover, two bus-bar regulation allows for better load management. By distributing the electrical load across two bus-bars, engineers can prevent any single bus-bar from becoming overloaded. This not only extends the lifespan of the equipment but also improves overall system reliability. In scenarios where demand fluctuates significantly, having two bus-bars facilitates smoother transitions and adjustments, thus maintaining a stable power supply.In addition to enhancing reliability and load management, two bus-bar regulation also contributes to improved safety. Electrical systems can be dangerous, and having a backup system in place reduces the likelihood of accidents. If one bus-bar fails, the other can take over, minimizing the risk of electrical fires or equipment damage. Furthermore, maintenance can be performed safely on one bus-bar while the other remains operational, allowing for continuous service without risking safety.Despite its advantages, implementing two bus-bar regulation does come with challenges. The initial costs can be higher due to the requirement for additional equipment and infrastructure. However, when considering the long-term benefits of increased reliability, safety, and efficiency, many organizations find that the investment is justified. Additionally, advancements in technology are continually reducing the costs associated with implementing such systems, making them more accessible to a wider range of facilities.In conclusion, two bus-bar regulation is a vital technique in modern electrical engineering that enhances the efficiency, reliability, and safety of power distribution systems. By providing redundancy and improving load management, this method ensures that critical services remain operational even in the face of challenges. As technology continues to evolve, the adoption of two bus-bar regulation is likely to become more prevalent, further solidifying its importance in the field of electrical engineering.

在电气工程领域，电力分配系统的效率和可靠性至关重要。为了增强这些方面，采用了“双母线调节”这一概念。这种技术涉及在电力系统中使用两个母线，以更有效地管理电流的流动。通过采用双母线调节，工程师可以确保电力的均匀分配，从而减少过载的风险，并增强电网的稳定性。要理解双母线调节的重要性，首先需要了解什么是母线。母线是一种导电材料，通常由铜或铝制成，作为电力分配的中心点。它连接多个电路，并允许电力从一个点有效转移到另一个点。在典型的电力分配设置中，可能会使用单个母线；然而，这可能导致脆弱性，尤其是在维护期间或发生故障时。双母线调节的实施通过提供冗余来解决这些脆弱性。通过使用两个母线，一个可以作为另一个的备份。这意味着如果一个母线需要下线进行维护或出现故障，另一个可以继续运行，确保电力供应不间断。这种冗余对于医院和数据中心等关键基础设施至关重要，在这些地方，停电可能会产生严重后果。此外，双母线调节还允许更好的负载管理。通过将电负荷分布在两个母线之间，工程师可以防止任何一个母线过载。这不仅延长了设备的使用寿命，还提高了整体系统的可靠性。在需求波动显著的情况下，拥有两个母线可以促进更平滑的过渡和调整，从而保持稳定的电力供应。除了提高可靠性和负载管理外，双母线调节还有助于提高安全性。电气系统可能是危险的，备份系统的存在降低了事故发生的可能性。如果一个母线发生故障，另一个可以接管，从而最小化电气火灾或设备损坏的风险。此外，可以安全地对一个母线进行维护，而另一个仍然保持运行，允许在不危及安全的情况下持续服务。尽管有其优势，但实施双母线调节也面临挑战。由于需要额外的设备和基础设施，初始成本可能较高。然而，考虑到提高的可靠性、安全性和效率的长期利益，许多组织发现这种投资是合理的。此外，技术的进步不断降低与实施此类系统相关的成本，使其对更广泛的设施更具可及性。总之，双母线调节是现代电气工程中的一项重要技术，增强了电力分配系统的效率、可靠性和安全性。通过提供冗余和改善负载管理，这种方法确保关键服务在面临挑战时仍能正常运行。随着技术的不断发展，双母线调节的采用可能会变得更加普遍，进一步巩固其在电气工程领域的重要性。