regenerator

简明释义

英[rɪˈdʒenəreɪtə(r)]美[riˈdʒenəˌreɪtər]

n. [化工] 再生器；改革者，更新者；蓄热器

英英释义

单词用法

同义词

反义词

例句

1.At these temperatures, solid materials have lower values for specific heat, so the regenerator must be made out of unexpected materials, such as cotton.

在这些温度下，固体材料有较低的值比热，所以再生必须作出了意想不到的材料，如棉花。

2.The base of regenerator must resist high temperature, hold necessary bearing capacity and durability.

设计的蓄热室底板既要有耐高温能力，又要有必要的承载力和耐久性。

3.Regenerator is a crucial component in the liquid desiccant air conditioning system.

摘要再生器是溶液除湿空调系统中的重要传热传质部件。

4.The possibility of utilizing regenerator flow resistance to suppress DC flow is theoretically and experimentally investigated.

本文理论和实验研究了通过改变回热器流阻进行直流抑制的可行性。

5.The dehumidifier and regenerator are the main parts of liquid desiccant equipments.

溶液除湿空调系统中最重要的部件是除湿器和再生器。

6.Either diatomite or ion exchange resin can be selected as regenerator according to customer's requirement.

根据用户需要可以采用硅藻土过滤器或离子交换树脂过滤器作为再生过滤器。

7.In our new design, the regenerator 再生器 improves energy efficiency significantly.

在我们的新设计中，regenerator 再生器显著提高了能效。

8.The heat exchanger works as a regenerator 再生器 to recover waste heat from the exhaust.

热交换器作为一个regenerator 再生器，回收废气中的废热。

9.The regenerator 再生器 is essential for reducing emissions in industrial processes.

在工业过程中，regenerator 再生器对减少排放至关重要。

10.We need to replace the old regenerator 再生器 to maintain optimal performance.

我们需要更换旧的regenerator 再生器以保持最佳性能。

11.The regenerator 再生器 helps in recovering heat that can be reused in the system.

该regenerator 再生器有助于回收可在系统中重复使用的热量。

作文

In the realm of engineering and technology, the concept of a regenerator (再生器) plays a crucial role in improving efficiency and sustainability. A regenerator is a device that recovers heat from exhaust gases and uses it to preheat incoming fluids, thereby reducing the energy required for heating processes. This principle is widely applied in various industries, including power generation, chemical processing, and even in household appliances. The importance of regenerators cannot be overstated, especially in today's world where energy conservation is paramount. By harnessing waste heat, regenerators help minimize fuel consumption and lower greenhouse gas emissions. For instance, in power plants, the implementation of a regenerator can significantly enhance the overall thermal efficiency of the system. When hot flue gases exit the boiler, they can be directed through a regenerator where they transfer their heat to water or air, which is then used to generate steam or provide heating. This process not only conserves energy but also leads to cost savings for operators.Moreover, the design of regenerators has evolved over time, with innovations aimed at maximizing heat transfer efficiency. Modern regenerators often utilize advanced materials and configurations to improve their performance. For example, ceramic materials are increasingly being used due to their high thermal resistance and ability to withstand extreme temperatures. Additionally, the integration of smart technology allows for real-time monitoring and optimization of regenerator performance, ensuring that systems operate at peak efficiency.In the context of environmental sustainability, regenerators offer a pathway to reduce reliance on fossil fuels. As industries strive to meet stricter emissions regulations, the adoption of regenerators becomes a strategic move towards greener operations. Furthermore, in residential settings, regenerators can be found in heat recovery ventilation systems, which improve indoor air quality while minimizing energy loss.Despite their numerous benefits, the implementation of regenerators is not without challenges. Initial installation costs can be high, and the complexity of integrating these systems into existing infrastructure may pose difficulties. However, the long-term savings and environmental benefits often outweigh these initial hurdles.In conclusion, the role of a regenerator (再生器) in modern engineering is vital for promoting energy efficiency and sustainability. As technology continues to advance, the potential applications and effectiveness of regenerators will likely expand, contributing significantly to global efforts in energy conservation and environmental protection. The future of energy systems will undoubtedly benefit from the continued development and integration of regenerators, making them an essential component in the quest for a more sustainable world.

在工程和技术领域中，regenerator（再生器）的概念在提高效率和可持续性方面发挥着至关重要的作用。regenerator 是一种从废气中回收热量并将其用于预热进入流体的装置，从而减少加热过程所需的能量。这个原理广泛应用于包括发电、化工处理甚至家用电器等各种行业。regenerator 的重要性不容小觑，特别是在今天这个节能至关重要的世界中。通过利用废热，regenerator 有助于最小化燃料消耗并降低温室气体排放。例如，在发电厂中，实施 regenerator 可以显著提高系统的整体热效率。当热烟气从锅炉排出时，可以通过 regenerator 转向，在这里它们将热量转移给水或空气，然后用于产生蒸汽或提供加热。这一过程不仅节约了能源，还为运营商带来了成本节省。此外，regenerator 的设计随着时间的推移而不断演进，创新旨在最大限度地提高热传递效率。现代的 regenerator 通常采用先进的材料和配置来改善其性能。例如，陶瓷材料因其高热阻和承受极端温度的能力而越来越多地被使用。此外，智能技术的集成允许对 regenerator 性能进行实时监控和优化，确保系统在最佳效率下运行。在环境可持续性的背景下，regenerator 提供了一条减少对化石燃料依赖的途径。随着工业努力满足更严格的排放法规，采用 regenerator 成为朝着更绿色操作的战略举措。此外，在住宅环境中，regenerator 可以在热回收通风系统中找到，这些系统在最小化能源损失的同时改善室内空气质量。尽管有许多好处，但实施 regenerator 并非没有挑战。初始安装成本可能很高，将这些系统集成到现有基础设施中的复杂性可能会带来困难。然而，长期的节省和环境效益往往超过了这些初始障碍。总之，regenerator（再生器）在现代工程中的作用对于促进能源效率和可持续性至关重要。随着技术的不断进步，regenerator 的潜在应用和有效性可能会扩展，为全球节能和环境保护的努力做出重要贡献。能源系统的未来无疑将受益于 regenerator 的持续发展和集成，使其成为追求更可持续世界的必不可少的组成部分。