binary cycle

简明释义

双汽循环

英英释义

例句

1.A binary cycle 二元循环 can operate efficiently at lower temperature differences compared to traditional systems.

与传统系统相比，二元循环 binary cycle可以在较低的温差下高效运行。

2.The binary cycle 二元循环 technology is gaining popularity in renewable energy applications.

在可再生能源应用中，二元循环 binary cycle技术越来越受欢迎。

3.Engineers are developing a binary cycle 二元循环 system to convert waste heat into electricity.

工程师们正在开发一个二元循环 binary cycle系统，将废热转化为电力。

4.The efficiency of the binary cycle 二元循环 process has been improved with new materials.

随着新材料的出现，二元循环 binary cycle过程的效率得到了提高。

5.The new geothermal power plant utilizes a binary cycle 二元循环 to enhance energy efficiency.

新的地热电厂利用二元循环 binary cycle来提高能效。

作文

The concept of a binary cycle is integral to understanding modern energy systems, particularly in the context of geothermal energy. A binary cycle power plant operates by using a secondary fluid with a lower boiling point than water. This allows for the efficient conversion of geothermal heat into electricity without directly using the geothermal water itself. The process begins when hot geothermal fluid is extracted from the earth. Instead of being used to drive a turbine directly, this hot fluid is passed through a heat exchanger. Here, it transfers its heat to the secondary fluid, which vaporizes and expands. The resulting vapor then drives a turbine connected to a generator, producing electricity.One of the most significant advantages of a binary cycle system is its environmental impact. Traditional geothermal plants can sometimes lead to the release of harmful gases or require significant amounts of water. In contrast, a binary cycle system minimizes these issues, as the geothermal fluid is reinjected back into the ground after passing through the heat exchanger. This closed-loop system not only conserves water but also reduces the risk of land subsidence and other geological impacts associated with geothermal extraction.Moreover, the binary cycle technology is adaptable, making it suitable for various geothermal resources, including low-temperature sites that were previously considered unfeasible for energy production. This adaptability opens up new opportunities for harnessing geothermal energy in regions where high-temperature resources are not available. As countries around the world seek to transition to renewable energy sources, the binary cycle presents a viable solution that can contribute significantly to sustainable energy goals.In addition to its technical advantages, the economic implications of adopting a binary cycle system are noteworthy. The initial investment may be higher compared to traditional geothermal systems, but the long-term operational efficiencies often lead to lower costs per megawatt-hour of electricity generated. Furthermore, the ability to utilize lower temperature resources means that more sites can be developed, increasing the overall capacity for geothermal energy production.As we look towards the future of energy generation, the role of the binary cycle will likely become more prominent. With ongoing advancements in technology and increasing awareness of climate change, the demand for clean, renewable energy sources is growing. The binary cycle system stands out as a promising option that aligns with these global trends. By harnessing the earth's natural heat while minimizing environmental impact, it exemplifies how innovation can lead to sustainable solutions in energy production.In conclusion, the binary cycle represents a significant advancement in geothermal energy technology. Its ability to efficiently convert low-temperature geothermal resources into electricity while maintaining environmental integrity makes it a key player in the transition to renewable energy. As we continue to explore and invest in sustainable energy solutions, the binary cycle will undoubtedly play an essential role in shaping a greener future for generations to come.

“二元循环”这一概念对于理解现代能源系统至关重要，尤其是在地热能的背景下。二元循环发电厂通过使用一种沸点低于水的二次流体来运行。这使得在不直接使用地热水的情况下，能够有效地将地热热量转化为电力。该过程始于从地下提取热地热流体。与其直接用于驱动涡轮机，不如将这种热流体通过热交换器。在这里，它将热量传递给二次流体，后者蒸发并膨胀。产生的蒸汽然后驱动连接到发电机的涡轮机，从而产生电力。二元循环系统的一个显著优势是其对环境的影响。传统的地热电厂有时会导致有害气体的释放或需要大量的水。相比之下，二元循环系统将这些问题降到最低，因为地热流体在通过热交换器后被重新注入地下。这一闭环系统不仅节约了水资源，而且减少了与地热开采相关的地面沉降和其他地质影响的风险。此外，二元循环技术具有适应性，使其适合各种地热资源，包括以前被认为不可行的低温场所。这种适应性为在高温资源不可用的地区开发地热能开辟了新的机会。随着世界各国寻求向可再生能源转型，二元循环提供了一种可行的解决方案，可以显著促进可持续能源目标。除了技术优势外，采用二元循环系统的经济影响也值得关注。初期投资可能高于传统地热系统，但长期运营效率往往导致每兆瓦时电力生成的成本更低。此外，利用较低温度资源的能力意味着可以开发更多场所，从而增加地热能生产的整体容量。展望未来，二元循环在能源生成中的角色可能会变得更加突出。随着技术的不断进步和对气候变化意识的增强，对清洁可再生能源的需求正在增长。二元循环系统作为一种与这些全球趋势相一致的有希望的选择脱颖而出。通过利用地球的自然热量，同时尽量减少环境影响，它示范了创新如何在能源生产中带来可持续解决方案。总之，二元循环代表了地热能源技术的一项重大进展。它能够有效地将低温地热资源转化为电力，同时保持环境完整性，使其成为向可再生能源转型的关键参与者。随着我们继续探索和投资可持续能源解决方案，二元循环无疑将在塑造更绿色的未来方面发挥重要作用，为子孙后代铺平道路。