battery cell

简明释义

1. 蓄电池组; 2. 蓄电池组电池; 3. 原电池; 4. 蓄电池;

英英释义

例句

1.The new smartphone model features a powerful battery cell 电池单元 that lasts longer than previous versions.

这款新智能手机型号配备了一个强大的电池单元，其续航时间比之前的版本更长。

2.You need to replace the battery cell 电池单元 if your remote control stops working.

如果你的遥控器停止工作，你需要更换电池单元。

3.To improve the performance, engineers designed a compact battery cell 电池单元 for electric vehicles.

为了提高性能，工程师为电动车设计了一个紧凑型的电池单元。

4.Researchers are exploring new materials for battery cells 电池单元 to enhance energy density.

研究人员正在探索新材料以增强电池单元的能量密度。

5.The battery cell 电池单元 in this laptop can be charged quickly and efficiently.

这款笔记本电脑中的电池单元可以快速高效地充电。

作文

In today's world, the importance of energy storage cannot be overstated. One of the key components in modern energy storage systems is the battery cell. A battery cell is a single electrochemical unit that converts chemical energy into electrical energy. Each battery cell consists of a positive electrode (cathode), a negative electrode (anode), and an electrolyte that facilitates the movement of ions between the electrodes. This fundamental design allows for the efficient storage and release of energy, making battery cells essential for various applications, from powering small electronic devices to large electric vehicles.The development of battery cells has significantly evolved over the years. Early batteries, such as the lead-acid battery, were primarily used in automobiles and other applications. However, with the rise of portable electronics and renewable energy systems, there has been a growing demand for more efficient and compact battery cells. Lithium-ion technology emerged as a game changer, offering higher energy density, lighter weight, and longer cycle life compared to traditional batteries. This innovation has led to the widespread adoption of battery cells in smartphones, laptops, and electric vehicles.Moreover, the environmental impact of battery cells has become a significant concern. As the demand for electric vehicles rises, so does the need for sustainable battery cell production and disposal methods. Researchers are actively exploring alternatives to lithium-ion technology, such as solid-state batteries and sodium-ion batteries, which promise to offer similar performance with less environmental impact. The goal is to create battery cells that not only meet our energy needs but also align with our commitment to sustainability.In addition to technological advancements, the manufacturing process of battery cells has also seen improvements. Automation and advanced materials science have enabled manufacturers to produce battery cells more efficiently and at a lower cost. This progress is crucial for making electric vehicles and renewable energy systems more accessible to the general public. As the production of battery cells becomes more streamlined, we can expect prices to decrease, further driving the adoption of clean energy technologies.The future of battery cells is promising, with ongoing research and development aimed at enhancing their performance and sustainability. Innovations such as fast-charging capabilities, increased lifespan, and improved safety features are on the horizon. As we continue to explore new materials and designs, the potential for battery cells to revolutionize the energy landscape is immense.In conclusion, understanding the role of battery cells in our daily lives is crucial as we transition towards a more sustainable energy future. These small yet powerful units are at the heart of many technologies we rely on today. As we strive for cleaner and more efficient energy solutions, the evolution of battery cells will play a pivotal role in shaping our energy landscape for generations to come.

在当今世界，能源储存的重要性不容小觑。现代能源储存系统中的关键组成部分之一是电池单元。电池单元是一个单一的电化学单元，将化学能转化为电能。每个电池单元由正极（阴极）、负极（阳极）和促进离子在电极之间移动的电解质组成。这种基本设计使得能量的高效储存和释放成为可能，使得电池单元在从小型电子设备到大型电动汽车的各种应用中至关重要。电池单元的发展多年来显著演变。早期的电池，如铅酸电池，主要用于汽车和其他应用。然而，随着便携式电子设备和可再生能源系统的兴起，对更高效和紧凑的电池单元的需求不断增加。锂离子技术作为一项颠覆性创新出现，提供了比传统电池更高的能量密度、更轻的重量和更长的循环寿命。这一创新导致了电池单元在智能手机、笔记本电脑和电动汽车中的广泛采用。此外，电池单元的环境影响已成为一个重要问题。随着电动汽车需求的上升，生产和处置可持续电池单元的方法的需求也随之增加。研究人员正在积极探索替代锂离子技术的方案，如固态电池和钠离子电池，这些方案承诺提供类似的性能，同时对环境的影响较小。目标是创造出不仅满足我们能源需求的电池单元，而且与我们对可持续发展的承诺相一致。除了技术进步，电池单元的制造过程也有所改善。自动化和先进材料科学使制造商能够更高效地生产电池单元，并降低成本。这一进展对于使电动汽车和可再生能源系统更易于公众接受至关重要。随着电池单元的生产变得更加流畅，我们可以期待价格下降，进一步推动清洁能源技术的采用。电池单元的未来充满希望，持续的研究和开发旨在提高其性能和可持续性。快速充电能力、延长使用寿命和改进安全特性等创新正在不断涌现。随着我们继续探索新材料和设计，电池单元革命化能源格局的潜力巨大。总之，理解电池单元在我们日常生活中的作用对于我们向更可持续的能源未来过渡至关重要。这些小而强大的单元是我们今天依赖的许多技术的核心。随着我们努力寻找更清洁、更高效的能源解决方案，电池单元的演变将在塑造未来几代人的能源格局中发挥关键作用。