core auxiliary cooling water

简明释义

堆芯辅助冷却水

英英释义

例句

1.The design of the plant includes redundancy for the core auxiliary cooling water 核心辅助冷却水 system to enhance safety.

该工厂的设计包括核心辅助冷却水系统的冗余以增强安全性。

2.In the event of a malfunction, the core auxiliary cooling water 核心辅助冷却水 supply must be redirected immediately.

在发生故障时，必须立即重新导向核心辅助冷却水供应。

3.The reactor's safety system relies on the flow of core auxiliary cooling water 核心辅助冷却水 to prevent overheating.

反应堆的安全系统依赖于流动的核心辅助冷却水来防止过热。

4.Regular maintenance checks are essential to ensure the core auxiliary cooling water 核心辅助冷却水 system is functioning properly.

定期维护检查对于确保核心辅助冷却水系统正常运作至关重要。

5.Engineers monitored the temperature of the core auxiliary cooling water 核心辅助冷却水 to ensure optimal performance.

工程师监测核心辅助冷却水的温度以确保最佳性能。

作文

In modern nuclear power plants, safety and efficiency are of utmost importance. One of the critical systems that contribute to these factors is the cooling system, particularly the core auxiliary cooling water. The core auxiliary cooling water refers to the water used to remove heat from the reactor core and other essential components during operation and in emergency situations. This system ensures that the reactor remains at a safe temperature, preventing overheating and potential meltdowns. The role of core auxiliary cooling water is crucial, especially during the initial phases of a reactor's operation and following any operational disturbances. In normal conditions, the primary cooling system manages the heat generated by the nuclear fission process. However, if there is a failure in the primary system, the core auxiliary cooling water acts as a backup, ensuring that the reactor core does not exceed safe temperature limits. This redundancy is vital for maintaining safety in nuclear facilities. Moreover, the core auxiliary cooling water system is designed to function under various scenarios, including loss of coolant accidents (LOCAs). During such incidents, the core auxiliary cooling water provides an additional layer of protection by circulating water around the core to absorb excess heat. This capability is essential for preventing catastrophic failures and ensuring that the reactor can be safely shut down if necessary. The engineering behind the core auxiliary cooling water system involves sophisticated technology and rigorous safety standards. Engineers must consider factors such as flow rates, temperature differentials, and the properties of the water used. The materials used in constructing the cooling system must withstand high temperatures and pressures to ensure reliability. Furthermore, regular maintenance and testing of the core auxiliary cooling water system are imperative to identify any potential issues before they become critical problems. In addition to its safety functions, the core auxiliary cooling water system also plays a role in the overall efficiency of a nuclear power plant. By effectively managing the heat produced during fission, this system helps optimize energy production. When the reactor operates within its ideal temperature range, it can generate electricity more efficiently, contributing to the plant's economic viability. Public perception of nuclear energy often hinges on safety concerns. Therefore, understanding the importance of systems like the core auxiliary cooling water is essential for fostering trust in nuclear technology. Education and transparency about how these systems work can help alleviate fears and promote informed discussions about the benefits and risks of nuclear energy. In conclusion, the core auxiliary cooling water system is a fundamental component of nuclear reactor safety and efficiency. Its ability to provide backup cooling during emergencies and maintain optimal operating conditions underscores its significance in the nuclear industry. As we move towards a future with increased reliance on nuclear energy, the importance of robust systems like the core auxiliary cooling water cannot be overstated. Ensuring their effectiveness will be key to the sustainable and safe operation of nuclear power plants worldwide.

在现代核电站中，安全性和效率至关重要。一个对这些因素至关重要的系统是冷却系统，特别是核心辅助冷却水。核心辅助冷却水指的是用于在运行和紧急情况下从反应堆核心及其他重要组件中去除热量的水。该系统确保反应堆保持在安全温度，防止过热和潜在的熔毁。核心辅助冷却水的作用至关重要，尤其是在反应堆运行的初始阶段以及在任何操作干扰后。在正常情况下，主要冷却系统管理由核裂变过程产生的热量。然而，如果主系统发生故障，核心辅助冷却水作为备用系统，确保反应堆核心不会超过安全温度限制。这种冗余对于维持核设施的安全至关重要。此外，核心辅助冷却水系统设计用于在各种场景下运行，包括冷却剂丧失事故（LOCA）。在此类事件中，核心辅助冷却水通过在核心周围循环水来吸收多余热量，从而提供额外的保护。这种能力对于防止灾难性故障并确保在必要时可以安全关闭反应堆至关重要。关于核心辅助冷却水系统的工程涉及复杂的技术和严格的安全标准。工程师必须考虑流量、温度差异和所用水的性质等因素。构建冷却系统所用的材料必须能够承受高温和高压，以确保可靠性。此外，定期维护和测试核心辅助冷却水系统对于在问题变得严重之前识别潜在问题至关重要。除了安全功能外，核心辅助冷却水系统还在核电站的整体效率中发挥作用。通过有效管理裂变过程中产生的热量，该系统有助于优化能源生产。当反应堆在理想温度范围内运行时，它可以更高效地发电，从而有助于电厂的经济可行性。公众对核能的看法往往取决于安全问题。因此，了解像核心辅助冷却水这样的系统的重要性对于促进对核技术的信任至关重要。教育和透明化这些系统的工作原理可以帮助减轻恐惧，促进关于核能的益处和风险的知情讨论。总之，核心辅助冷却水系统是核反应堆安全和效率的基本组成部分。它在紧急情况下提供备用冷却并维持最佳运行条件的能力强调了它在核工业中的重要性。随着我们向更依赖核能的未来迈进，像核心辅助冷却水这样的强大系统的重要性不容小觑。确保其有效性将是全球核电站可持续和安全运营的关键。