monolithic cell

简明释义

单片单元

英英释义

例句

1.Using a monolithic cell can significantly reduce manufacturing costs.

使用单体电池可以显著降低制造成本。

2.The monolithic cell structure allows for better thermal management in high-performance devices.

这种单体电池结构允许在高性能设备中更好地进行热管理。

3.The team developed a prototype that features a monolithic cell design for compactness.

该团队开发了一种原型，采用了紧凑型的单体电池设计。

4.Researchers are exploring the potential of monolithic cells in solar energy applications.

研究人员正在探索单体电池在太阳能应用中的潜力。

5.The design of the new battery incorporates a monolithic cell to enhance efficiency.

新电池的设计采用了一个单体电池以提高效率。

作文

In the field of technology and materials science, the term monolithic cell refers to a type of structure that is made from a single, continuous piece of material. This concept is particularly important in the design and manufacturing of various components, including batteries, solar cells, and even architectural elements. The advantages of using a monolithic cell are numerous, as it often leads to improved performance, increased durability, and reduced production costs. For instance, in the realm of solar energy, a monolithic cell can enhance the efficiency of solar panels. Traditional solar panels are often constructed from multiple smaller cells, which can lead to inefficiencies due to the connections between these cells. However, when a solar panel is designed as a monolithic cell, it eliminates these connections and allows for a more uniform absorption of sunlight. This not only maximizes energy conversion but also minimizes the chances of failure due to poor connections.Moreover, the use of monolithic cells in batteries has revolutionized energy storage solutions. Batteries that utilize a monolithic cell design tend to have higher energy densities and longer lifespans. This is because the absence of joints or seams reduces the likelihood of leakage or corrosion, which can significantly impair battery performance over time. Additionally, the manufacturing process for monolithic cells can be streamlined, resulting in lower costs and faster production times.In architecture, the idea of a monolithic cell can be applied to the construction of buildings. Structures built from a single material or as a single unit can offer greater structural integrity and aesthetic appeal. For example, monolithic domes are known for their strength and energy efficiency. The seamless nature of these structures allows for better insulation and less energy loss, making them an attractive option for sustainable building practices.Despite the clear benefits of monolithic cells, there are also challenges associated with their implementation. One major issue is the difficulty in repairing or replacing a monolithic cell once it has been damaged. In contrast to traditional multi-component designs, where individual parts can be swapped out, a monolithic cell requires complete replacement if any part of it fails. This can lead to increased costs and resource waste over time.Furthermore, the production of monolithic cells often requires advanced technology and materials, which may not be readily available in all regions. This can limit the widespread adoption of monolithic cell designs, particularly in developing areas where resources are scarce.In conclusion, the concept of a monolithic cell plays a crucial role in various industries, offering significant advantages in terms of efficiency, durability, and cost-effectiveness. While there are challenges to consider, the ongoing advancements in technology and materials science continue to pave the way for the broader application of monolithic cells. As we move towards a more sustainable future, the importance of such innovative designs will undoubtedly grow, making the understanding of monolithic cells essential for both professionals and enthusiasts alike.

在技术和材料科学领域，术语单体电池指的是由单一、连续的材料制成的一种结构。这个概念在各种组件的设计和制造中尤为重要，包括电池、太阳能电池以及建筑元素。使用单体电池的优点是显而易见的，因为它通常会带来更高的性能、增加的耐用性和降低的生产成本。例如，在太阳能领域，单体电池可以提高太阳能电池板的效率。传统的太阳能电池板通常由多个较小的电池构成，这可能会由于这些电池之间的连接而导致效率低下。然而，当太阳能电池板设计为单体电池时，它消除了这些连接，使得阳光的吸收更加均匀。这不仅最大化了能量转换，还最小化了由于连接不良而导致的故障的可能性。此外，单体电池在电池中的应用也彻底改变了能源存储解决方案。利用单体电池设计的电池往往具有更高的能量密度和更长的使用寿命。这是因为缺少接缝或缝隙减少了泄漏或腐蚀的可能性，这些因素会显著影响电池的长期性能。此外，单体电池的生产过程可以简化，从而降低成本并加快生产时间。在建筑领域，单体电池的概念可以应用于建筑物的建造。由单一材料或作为单一单元建造的结构可以提供更大的结构完整性和美学吸引力。例如，单体圆顶因其强度和能效而闻名。这些结构的无缝特性允许更好的绝缘和更少的能量损失，使其成为可持续建筑实践的理想选择。尽管单体电池的明显优势，但在其实施过程中也存在挑战。其中一个主要问题是，一旦单体电池受损，维修或更换的难度。与传统的多组件设计相比，后者可以更换单个部件，而单体电池则需要在任何部分失败时进行完全更换。这可能导致长期的成本增加和资源浪费。此外，单体电池的生产通常需要先进的技术和材料，这些在所有地区可能并不容易获得。这可能限制单体电池设计的广泛采用，特别是在资源稀缺的发展地区。总之，单体电池的概念在各个行业中发挥着至关重要的作用，在效率、耐用性和成本效益方面提供了显著的优势。尽管需要考虑挑战，但技术和材料科学的不断进步继续为单体电池设计的更广泛应用铺平道路。随着我们朝着更可持续的未来迈进，这种创新设计的重要性无疑会增加，因此理解单体电池对专业人士和爱好者来说都是必不可少的。