thermoelectric cell

简明释义

热元件

英英释义

例句

1.A thermoelectric cell 热电池 can convert waste heat from industrial processes into electricity.

热电池可以将工业过程中的废热转化为电能。

2.In space missions, thermoelectric cells 热电池 are used to power spacecraft using heat from radioactive decay.

在太空任务中，热电池用于利用放射性衰变产生的热量为航天器供电。

3.The efficiency of the thermoelectric cell 热电池 can significantly impact energy conversion in renewable technologies.

热电池的效率可以显著影响可再生能源技术中的能量转换。

4.Researchers are developing new materials for thermoelectric cells 热电池 to improve their performance.

研究人员正在开发新材料以提高热电池的性能。

5.The thermoelectric cell 热电池 generates electricity by exploiting the Seebeck effect.

热电池通过利用塞贝克效应产生电力。

作文

In recent years, the quest for sustainable energy solutions has led to significant advancements in various technologies. One of the most promising innovations in this field is the development of the thermoelectric cell (热电池). These devices convert heat directly into electricity through the Seebeck effect, which occurs when there is a temperature difference across a material. This unique ability makes thermoelectric cells (热电池) an attractive option for harnessing waste heat from industrial processes, automotive engines, and even body heat.The principle behind thermoelectric cells (热电池) is relatively simple yet powerful. When one side of the cell is heated while the other remains cool, charge carriers within the material migrate from the hot side to the cold side. This movement generates a voltage, which can then be harnessed to power electronic devices or charge batteries. The efficiency of thermoelectric cells (热电池) depends on the materials used, with certain semiconductors proving more effective than others.Historically, thermoelectric cells (热电池) were primarily used in niche applications, such as space probes and remote sensors, where conventional power sources are impractical. However, as the demand for renewable energy sources grows, researchers are exploring new materials and designs that could enhance the efficiency and reduce the costs of thermoelectric cells (热电池). Recent studies have focused on nanostructured materials, which can significantly improve the thermoelectric performance by increasing the amount of heat that can be converted into electrical energy.One of the key advantages of thermoelectric cells (热电池) is their ability to operate without moving parts, making them highly reliable and requiring minimal maintenance. This characteristic opens up numerous possibilities for their use in various applications, including waste heat recovery systems in factories and power generation in remote locations. Additionally, thermoelectric cells (热电池) can be integrated into wearable technology, providing a way to convert body heat into usable electrical energy, which could revolutionize how we power our devices.Despite their potential, several challenges remain in the widespread adoption of thermoelectric cells (热电池). The current efficiency levels are still relatively low compared to traditional power generation methods. Researchers are actively working to improve the thermoelectric figure of merit (ZT), a dimensionless number that indicates the efficiency of a thermoelectric material. Achieving higher ZT values will be crucial for making thermoelectric cells (热电池) a viable alternative to conventional energy sources.In conclusion, thermoelectric cells (热电池) represent a fascinating area of research with the potential to contribute significantly to the transition towards sustainable energy solutions. As technology advances and materials science progresses, it is likely that we will see increased implementation of thermoelectric cells (热电池) in various sectors. Their ability to convert waste heat into electricity not only offers a means of improving energy efficiency but also aligns with global efforts to reduce carbon emissions and combat climate change. The future of energy may very well depend on the successful integration of thermoelectric cells (热电池) into our everyday lives.

近年来，寻找可持续能源解决方案的努力在各项技术中取得了显著进展。其中最有前景的创新之一是热电池（thermoelectric cell）的发展。这些设备通过塞贝克效应（Seebeck effect）将热量直接转化为电能，该效应发生在材料的温度差异存在时。这种独特的能力使得热电池（thermoelectric cell）成为从工业过程、汽车发动机甚至人体热量中获取废热的理想选择。热电池（thermoelectric cell）的原理相对简单但功能强大。当电池的一侧被加热而另一侧保持凉爽时，材料中的载流子会从热的一侧迁移到冷的一侧。这一运动产生电压，可以用来为电子设备供电或为电池充电。热电池（thermoelectric cell）的效率取决于所使用的材料，一些半导体比其他材料更有效。历史上，热电池（thermoelectric cell）主要用于一些小众应用，如太空探测器和远程传感器，在这些场合下传统电源并不实用。然而，随着对可再生能源需求的增长，研究人员正在探索新材料和新设计，以提高热电池（thermoelectric cell）的效率并降低成本。最近的研究集中在纳米结构材料上，这些材料可以通过增加可转化为电能的热量来显著改善热电性能。热电池（thermoelectric cell）的一个关键优势是它们能够在没有运动部件的情况下运行，从而使其高度可靠且维护需求最小。这一特性为其在各种应用中的使用开辟了众多可能性，包括工厂中的废热回收系统和偏远地区的发电。此外，热电池（thermoelectric cell）还可以集成到可穿戴技术中，提供一种将体热转化为可用电能的方式，这可能会彻底改变我们为设备供电的方式。尽管潜力巨大，但热电池（thermoelectric cell）的广泛应用仍面临几项挑战。目前的效率水平仍然相对较低，无法与传统发电方法相比。研究人员正在积极努力提高热电优值（ZT），这是一个无量纲数，表示热电材料的效率。实现更高的ZT值对于使热电池（thermoelectric cell）成为传统能源来源的可行替代品至关重要。总之，热电池（thermoelectric cell）代表了一个迷人的研究领域，具有显著贡献于向可持续能源解决方案过渡的潜力。随着技术的进步和材料科学的发展，我们可能会看到热电池（thermoelectric cell）在各个领域的实施增加。它们将废热转化为电能的能力不仅提供了一种提高能源效率的方法，还与全球减少碳排放和应对气候变化的努力相一致。未来的能源很可能依赖于成功将热电池（thermoelectric cell）融入我们的日常生活。