systems for nuclear auxiliary power
简明释义
核辅助动力系统
英英释义
Systems designed to provide supplementary power to nuclear facilities, ensuring operational reliability and safety during normal operations or emergencies. | 旨在为核设施提供辅助电力的系统,确保在正常操作或紧急情况下的运行可靠性和安全性。 |
例句
1.Upgrading the systems for nuclear auxiliary power is essential for improving overall plant efficiency.
升级核辅助电力系统对提高整体厂效率至关重要。
2.The systems for nuclear auxiliary power must comply with international safety standards.
核辅助电力系统必须符合国际安全标准。
3.The safety protocols include checks on the systems for nuclear auxiliary power during routine inspections.
安全协议包括在例行检查中对核辅助电力系统的检查。
4.Engineers are currently testing systems for nuclear auxiliary power in various operational scenarios.
工程师们正在不同操作场景中测试核辅助电力系统。
5.The new reactor design incorporates advanced systems for nuclear auxiliary power to ensure uninterrupted energy supply.
新反应堆设计采用先进的核辅助电力系统以确保不间断的能源供应。
作文
In the modern world, energy demands are continuously rising, and the quest for sustainable and efficient power sources has never been more critical. One of the promising areas of research and development is in the field of nuclear energy. Specifically, the implementation of systems for nuclear auxiliary power plays a vital role in enhancing the efficiency and reliability of nuclear power plants. These systems are designed to provide essential support functions during normal operations and emergency situations, ensuring that the plant can maintain safety and operational integrity.The primary function of systems for nuclear auxiliary power is to supply power to critical components of a nuclear facility when the main power source is unavailable or compromised. For instance, in the event of a grid failure, these auxiliary systems can ensure that cooling systems remain operational, preventing overheating of the reactor core. This capability is crucial because overheating can lead to severe accidents, as seen in historical incidents like Chernobyl and Fukushima.Furthermore, systems for nuclear auxiliary power are not only about providing backup power; they also enhance the overall resilience of nuclear facilities. By integrating advanced technologies such as battery storage and renewable energy sources, these systems can improve the sustainability of nuclear operations. For example, solar panels can be used in conjunction with auxiliary power systems to provide an additional layer of energy security, reducing reliance on external power grids and fossil fuels.The design and implementation of systems for nuclear auxiliary power involve rigorous engineering and safety standards. Engineers must ensure that these systems can function under various conditions, including extreme weather events and potential seismic activity. The redundancy built into these systems is paramount; multiple layers of backup power ensure that even if one component fails, others can take over seamlessly. This level of reliability is essential for maintaining public trust in nuclear energy.Moreover, the regulatory framework surrounding systems for nuclear auxiliary power is stringent. Regulatory bodies require thorough testing and validation of these systems before they can be deployed in operational facilities. This process includes simulations of emergency scenarios to assess how well these systems perform under stress. Only after meeting all safety and performance criteria can a nuclear facility be licensed to operate with these auxiliary systems in place.In conclusion, systems for nuclear auxiliary power are a cornerstone of modern nuclear energy infrastructure. They not only provide essential backup power but also contribute to the overall safety and resilience of nuclear power plants. As the global community continues to seek cleaner and more efficient energy solutions, the importance of these systems will only grow. Investing in advanced technologies and robust engineering practices for auxiliary power systems will help ensure that nuclear energy remains a viable and safe option for meeting future energy demands.
在现代世界,能源需求不断上升,对可持续和高效电源的追求比以往任何时候都更加重要。核能领域的研究和开发是一个有前景的领域。具体来说,实施核辅助电源系统在提高核电厂的效率和可靠性方面发挥着至关重要的作用。这些系统旨在在正常运行和紧急情况下提供必要的支持功能,确保工厂能够保持安全和操作完整性。核辅助电源系统的主要功能是在主要电源不可用或受到威胁时,为核设施的关键组件提供电力。例如,在电网故障的情况下,这些辅助系统可以确保冷却系统保持运行,从而防止反应堆核心过热。这一能力至关重要,因为过热可能导致严重事故,正如切尔诺贝利和福岛等历史事件所示。此外,核辅助电源系统不仅仅是提供备用电源;它们还增强了核设施的整体弹性。通过集成电池存储和可再生能源等先进技术,这些系统可以提高核操作的可持续性。例如,太阳能电池板可以与辅助电源系统结合使用,以提供额外的能源安全层,减少对外部电网和化石燃料的依赖。核辅助电源系统的设计和实施涉及严格的工程和安全标准。工程师必须确保这些系统能够在各种条件下运行,包括极端天气事件和潜在的地震活动。这些系统中内置的冗余性至关重要;多个备份电源确保即使一个组件失败,其他组件也可以无缝接管。这种可靠性对于维护公众对核能的信任至关重要。此外,围绕核辅助电源系统的监管框架也非常严格。监管机构要求在这些系统可以部署到运营设施之前进行全面的测试和验证。这个过程包括模拟紧急场景,以评估这些系统在压力下的表现。只有在满足所有安全和性能标准之后,核设施才能获得使用这些辅助系统的运营许可证。总之,核辅助电源系统是现代核能基础设施的基石。它们不仅提供必要的备用电源,还为核电厂的整体安全性和弹性做出贡献。随着全球社会继续寻求更清洁、更高效的能源解决方案,这些系统的重要性只会增加。投资于先进技术和强大的工程实践,以实现辅助电源系统,将有助于确保核能在满足未来能源需求方面仍然是一种可行且安全的选择。
相关单词
