rotary regenerator

简明释义

旋转式回热器

英英释义

例句

1.The rotary regenerator works by transferring heat between incoming and outgoing air streams.

旋转再生器通过在进气和排气流之间转移热量来工作。

2.The efficiency of the heating system improved significantly after installing a new rotary regenerator.

在安装了新的旋转再生器后，供热系统的效率显著提高。

3.A well-designed rotary regenerator can reduce energy consumption by up to 30%.

设计良好的旋转再生器可以将能耗减少多达30%。

4.We installed a rotary regenerator to enhance the energy efficiency of our HVAC system.

我们安装了一个旋转再生器以提高我们的暖通空调系统的能效。

5.In industrial applications, a rotary regenerator can recover heat from exhaust gases.

在工业应用中，旋转再生器可以从废气中回收热量。

作文

In modern engineering and energy systems, the efficiency of heat exchange processes is crucial for optimizing performance and reducing energy consumption. One remarkable device that plays a significant role in this regard is the rotary regenerator. A rotary regenerator is a type of heat exchanger that utilizes a rotating element to transfer heat between two fluids, typically air or gas. This innovative design allows for effective heat recovery, which contributes to enhanced energy efficiency in various applications, including power plants, industrial processes, and HVAC systems.The fundamental principle behind a rotary regenerator involves using a rotating wheel or drum that is partially immersed in the hot exhaust gases and the cooler incoming air. As the wheel rotates, it absorbs heat from the exhaust gases and then transfers that heat to the incoming cooler air when it comes into contact with it. This process significantly reduces the energy required to heat the incoming air, thereby improving the overall thermal efficiency of the system.One of the key advantages of a rotary regenerator is its ability to achieve high heat recovery rates. Unlike traditional fixed heat exchangers, which often have limitations in terms of surface area and flow arrangement, the rotating design of the rotary regenerator allows for continuous and dynamic heat transfer. This results in better temperature equalization and a more efficient use of energy resources.Moreover, rotary regenerators are particularly beneficial in applications where large volumes of air or gas need to be processed. For instance, in power generation facilities, the use of a rotary regenerator can lead to substantial reductions in fuel consumption and greenhouse gas emissions. By recovering waste heat that would otherwise be lost, these devices contribute to a more sustainable energy landscape.In addition to their environmental benefits, rotary regenerators also offer economic advantages. The initial investment in such technology can be offset by the long-term savings achieved through reduced energy costs. Industries that implement rotary regenerators often experience improved operational efficiency and lower overall expenses, making them an attractive option for businesses looking to enhance their bottom line while being environmentally responsible.However, it is essential to consider the maintenance and operational aspects of rotary regenerators. While they are designed for durability, regular inspections and maintenance are necessary to ensure optimal performance. Factors such as dust accumulation, wear and tear on moving parts, and changes in operating conditions can affect the efficiency of the heat exchange process. Therefore, a well-planned maintenance schedule is crucial for maximizing the lifespan and effectiveness of a rotary regenerator.In conclusion, the rotary regenerator is a vital component in the quest for energy efficiency and sustainability in various industries. Its innovative design and ability to recover waste heat make it an invaluable tool for reducing energy consumption and minimizing environmental impact. As technology continues to advance, the role of rotary regenerators will likely expand, paving the way for even greater improvements in energy management and resource utilization. Embracing such technologies is not only beneficial for individual organizations but also for the planet as a whole, as we strive towards a more energy-efficient future.

在现代工程和能源系统中，热交换过程的效率对于优化性能和减少能耗至关重要。一个在这方面发挥重要作用的显著设备是旋转再生器。旋转再生器是一种利用旋转元件在两种流体（通常是空气或气体）之间传递热量的热交换器。这种创新设计使有效的热回收成为可能，有助于提高发电厂、工业过程和暖通空调系统等各种应用中的能源效率。旋转再生器的基本原理涉及使用一个部分浸入热废气和冷进气中的旋转轮或鼓。当轮子旋转时，它从废气中吸收热量，然后在与冷进气接触时将这些热量转移给它。这个过程显著减少了加热进气所需的能量，从而提高了系统的整体热效率。旋转再生器的一个关键优势是其能够实现高热回收率。与传统的固定热交换器相比，后者在表面积和流动布置方面常常存在限制，旋转再生器的旋转设计允许连续和动态的热量转移。这导致更好的温度均衡和更有效的能源资源使用。此外，旋转再生器在需要处理大量空气或气体的应用中尤其有利。例如，在发电设施中，使用旋转再生器可以显著减少燃料消耗和温室气体排放。通过回收本会被浪费的废热，这些设备有助于实现更可持续的能源格局。除了环境效益外，旋转再生器还提供经济优势。对这种技术的初始投资可以通过降低长期能源成本来抵消。实施旋转再生器的行业通常会经历运营效率的改善和总体费用的降低，使其成为希望提升业绩的企业的吸引选项，同时又能负责任地对待环境。然而，考虑旋转再生器的维护和操作方面也至关重要。尽管它们设计得很耐用，但定期检查和维护是确保最佳性能的必要条件。灰尘积聚、运动部件磨损以及操作条件变化等因素都可能影响热交换过程的效率。因此，精心规划的维护计划对于最大化旋转再生器的使用寿命和有效性至关重要。总之，旋转再生器是实现各行业能源效率和可持续性的重要组成部分。它的创新设计和回收废热的能力使其成为减少能源消耗和最小化环境影响的宝贵工具。随着技术的不断进步，旋转再生器的作用可能会扩大，为能源管理和资源利用的进一步改善铺平道路。接受这些技术不仅对个别组织有利，而且对整个星球也是如此，因为我们努力走向更高效的能源未来。