combined nuclear and gas turbine

简明释义

核动力和燃气轮机联合动力设备

英英释义

例句

1.The combined nuclear and gas turbine design allows for greater flexibility in energy production.

这种组合核能和燃气轮机设计允许在能源生产中具有更大的灵活性。

2.Engineers are exploring the benefits of a combined nuclear and gas turbine approach to reduce emissions.

工程师们正在探索组合核能和燃气轮机方法的好处，以减少排放。

3.A combined nuclear and gas turbine facility can provide a stable power supply even during peak demand.

一个组合核能和燃气轮机设施可以在高峰需求期间提供稳定的电力供应。

4.The new power plant utilizes a combined nuclear and gas turbine system for improved efficiency.

这座新电厂采用了组合核能和燃气轮机系统以提高效率。

5.Investments in combined nuclear and gas turbine technologies are expected to rise significantly in the coming years.

对组合核能和燃气轮机技术的投资预计将在未来几年显著增加。

作文

In the quest for sustainable and efficient energy production, the concept of a combined nuclear and gas turbine system has emerged as a promising solution. This innovative approach integrates two powerful technologies: nuclear power, known for its ability to generate large amounts of energy with minimal carbon emissions, and gas turbines, which offer rapid response times and high efficiency. By combining these two methods, we can potentially revolutionize the way we produce electricity, making it cleaner and more reliable.The fundamental principle behind a combined nuclear and gas turbine system lies in its ability to utilize the strengths of both energy sources. Nuclear power plants operate by using nuclear fission to produce heat, which is then used to generate steam that drives turbines. This process is highly efficient and produces a significant amount of energy without emitting greenhouse gases. On the other hand, gas turbines burn natural gas to produce electricity and are known for their quick startup times and flexibility in operation.When these two systems are combined, the result is a hybrid energy generation model that can provide both baseload and peak load power. The nuclear component can supply a steady flow of electricity, while the gas turbine can be ramped up quickly to meet sudden spikes in demand. This dual capability ensures that energy supply remains stable, even during periods of fluctuating demand.Furthermore, the integration of a combined nuclear and gas turbine system can lead to enhanced overall efficiency. By utilizing waste heat from the nuclear reactor to preheat the gas turbine's combustion air, we can improve the thermal efficiency of both systems. This not only maximizes energy output but also minimizes fuel consumption, resulting in lower operational costs and reduced environmental impact.Another significant advantage of this hybrid system is its potential to support renewable energy sources. As the world shifts towards greener alternatives, the need for reliable backup power becomes crucial. A combined nuclear and gas turbine system can provide the necessary reliability to complement intermittent renewable sources such as wind and solar. During periods when renewable generation is low, the nuclear and gas components can work together to ensure a continuous and stable energy supply.However, the implementation of combined nuclear and gas turbine systems is not without challenges. The initial investment required for the construction of such facilities can be substantial, and there are regulatory hurdles to navigate given the complexities of nuclear energy. Additionally, public perception of nuclear power remains a contentious issue, which can complicate project approvals and community acceptance.Despite these challenges, the potential benefits of a combined nuclear and gas turbine system are significant. As the global demand for energy continues to rise, finding ways to produce electricity that are both sustainable and efficient will be paramount. By harnessing the strengths of nuclear and gas turbine technologies, we can move closer to achieving a balanced and resilient energy future.In conclusion, the combined nuclear and gas turbine system represents an innovative approach to energy generation that could play a critical role in our transition to a more sustainable energy landscape. By leveraging the advantages of both nuclear and gas technologies, we can create a flexible, efficient, and environmentally friendly energy system that meets the needs of today while paving the way for a cleaner tomorrow.

在追求可持续和高效的能源生产过程中，联合核能与燃气轮机系统的概念作为一种有前景的解决方案浮出水面。这种创新的方法结合了两种强大的技术：核能以其能够以最小的碳排放产生大量能源而闻名，而燃气轮机则以快速响应时间和高效率著称。通过将这两种方法结合起来，我们可以潜在地革新电力生产方式，使其更加清洁和可靠。联合核能与燃气轮机系统的基本原理在于其能够利用两种能源的优势。核电厂通过利用核裂变产生热量，然后用这些热量产生蒸汽驱动涡轮机。这个过程效率极高，并且在不排放温室气体的情况下产生大量能量。另一方面，燃气轮机燃烧天然气来生产电力，以其快速启动时间和灵活性而闻名。当这两个系统结合时，结果是一个混合能源生成模型，可以提供基础负荷和峰值负荷电力。核能组件可以提供稳定的电力流，而燃气轮机可以迅速提升以满足突发的需求高峰。这种双重能力确保了即使在需求波动的时期，能源供应也保持稳定。此外，整合联合核能与燃气轮机系统可以提高整体效率。通过利用核反应堆的废热来预热燃气轮机的燃烧空气，我们可以提高两个系统的热效率。这不仅最大化了能源输出，还最小化了燃料消耗，从而降低运营成本并减少环境影响。这一混合系统的另一个显著优势是它能够支持可再生能源。在全球向更绿色替代品转型时，可靠的备用电源的需求变得至关重要。联合核能与燃气轮机系统可以提供必要的可靠性，以补充间歇性的可再生能源，如风能和太阳能。在可再生发电低迷的时期，核能和燃气组件可以共同工作，以确保连续和稳定的能源供应。然而，实施联合核能与燃气轮机系统并非没有挑战。建设此类设施所需的初始投资可能相当可观，而且由于核能的复杂性，必须克服监管障碍。此外，公众对核能的看法仍然是一个有争议的问题，这可能会使项目批准和社区接受变得复杂。尽管面临这些挑战，联合核能与燃气轮机系统的潜在好处是显著的。随着全球对能源的需求不断上升，寻找可持续和高效的电力生产方式将变得至关重要。通过利用核能和燃气轮机技术的优势，我们可以更接近实现平衡和韧性的能源未来。总之，联合核能与燃气轮机系统代表了一种创新的能源生成方法，可能在我们向更可持续的能源格局转型中发挥关键作用。通过利用核能和燃气技术的优势，我们可以创建一个灵活、高效和环保的能源系统，满足当今的需求，同时为更清洁的明天铺平道路。