core auxiliary heat exchanger

简明释义

堆芯辅助热交换器

英英释义

例句

1.During the winter months, the core auxiliary heat exchanger (核心辅助热交换器) helps to maintain indoor temperatures.

在冬季，核心辅助热交换器帮助维持室内温度。

2.The core auxiliary heat exchanger (核心辅助热交换器) plays a critical role in the heating system's overall efficiency.

核心辅助热交换器在供暖系统的整体效率中起着关键作用。

3.The efficiency of the system improved significantly after upgrading the core auxiliary heat exchanger (核心辅助热交换器).

在升级了核心辅助热交换器后，系统的效率显著提高。

4.Regular maintenance of the core auxiliary heat exchanger (核心辅助热交换器) is essential for optimal performance.

定期维护核心辅助热交换器对于最佳性能至关重要。

5.Our engineers designed a new model of the core auxiliary heat exchanger (核心辅助热交换器) to reduce energy consumption.

我们的工程师设计了一种新的核心辅助热交换器型号，以减少能源消耗。

作文

In modern engineering, particularly in the fields of energy and thermal management, the term core auxiliary heat exchanger plays a significant role. Understanding its function and importance can provide insights into how various systems operate efficiently. A core auxiliary heat exchanger is a device that facilitates the transfer of heat between two or more fluids, ensuring that energy is utilized effectively in processes such as heating, cooling, and power generation.The primary purpose of a core auxiliary heat exchanger is to enhance energy efficiency by reclaiming waste heat from industrial processes or power plants. This reclaimed heat can then be used for other purposes, such as preheating incoming fluids or generating steam for turbines. By doing so, organizations can significantly reduce their energy consumption and operational costs, which is increasingly important in today's economy where sustainability is a priority.One common application of the core auxiliary heat exchanger is in combined cycle power plants. These facilities utilize both gas and steam turbines to generate electricity. The exhaust heat from the gas turbine is captured by the core auxiliary heat exchanger, which then transfers this heat to water, converting it into steam. This steam is subsequently used to drive a steam turbine, thereby increasing the overall efficiency of the power plant. Such systems exemplify how a core auxiliary heat exchanger can contribute to more sustainable energy practices.Furthermore, the design of a core auxiliary heat exchanger can vary based on its intended application. It may be a shell-and-tube, plate, or finned-tube type, each offering distinct advantages in terms of heat transfer efficiency, maintenance, and space requirements. Engineers must carefully consider these factors when selecting the appropriate type of heat exchanger for a specific application.In addition to energy production, core auxiliary heat exchangers are also widely used in HVAC (Heating, Ventilation, and Air Conditioning) systems. In these systems, they help manage indoor climates by transferring heat between indoor and outdoor environments. For instance, during winter months, a core auxiliary heat exchanger can extract heat from the exhaust air and transfer it to the incoming fresh air, thereby reducing the energy required to heat the building.Moreover, advancements in technology have led to the development of more efficient core auxiliary heat exchangers. Innovations such as enhanced surface materials and designs that promote turbulent flow can improve heat transfer rates and reduce fouling, which is the accumulation of unwanted material on the heat exchanger surfaces. These improvements not only enhance performance but also extend the lifespan of the equipment, making them more cost-effective in the long run.In conclusion, the core auxiliary heat exchanger is a vital component in many modern systems, from power generation to climate control. Its ability to efficiently transfer heat contributes to energy conservation and sustainability efforts across various industries. As technology continues to advance, the role of the core auxiliary heat exchanger will likely become even more critical in our pursuit of efficient energy use and environmental responsibility.

在现代工程中，尤其是在能源和热管理领域，术语核心辅助热交换器发挥着重要作用。理解其功能和重要性可以提供对各种系统如何高效运作的见解。核心辅助热交换器是一种促进两种或多种流体之间热量转移的设备，确保在加热、冷却和发电等过程中有效利用能量。核心辅助热交换器的主要目的是通过回收工业过程或发电厂的废热来提高能源效率。这种回收的热量可以用于其他目的，比如预热进入的流体或为涡轮机发电。通过这样做，组织可以显著降低能源消耗和运营成本，这在今天以可持续性为优先事项的经济中显得尤为重要。核心辅助热交换器的一个常见应用是在联合循环发电厂。这些设施同时利用燃气和蒸汽涡轮机发电。燃气涡轮的废气热量被核心辅助热交换器捕获，然后将这部分热量传递给水，使其转化为蒸汽。随后，这些蒸汽被用来驱动蒸汽涡轮机，从而提高发电厂的整体效率。这些系统展示了核心辅助热交换器如何为更可持续的能源实践做出贡献。此外，核心辅助热交换器的设计可以根据其预期应用而有所不同。它可以是壳管式、板式或鳍片式，每种类型在热量转移效率、维护和空间要求方面都有不同的优势。工程师在选择特定应用的合适热交换器时，必须仔细考虑这些因素。除了能源生产，核心辅助热交换器还广泛应用于HVAC（供暖、通风和空调）系统。在这些系统中，它们通过在室内和室外环境之间转移热量来帮助管理室内气候。例如，在冬季，核心辅助热交换器可以从排气空气中提取热量，并将其转移到进入的新鲜空气中，从而减少加热建筑物所需的能量。此外，技术的进步使得更加高效的核心辅助热交换器得以开发。诸如增强表面材料和促进湍流流动的设计等创新可以提高热量转移速率并减少污垢积聚，即热交换器表面上不需要的材料的积累。这些改进不仅提高了性能，还延长了设备的使用寿命，使其在长期内更加经济高效。总之，核心辅助热交换器是许多现代系统中的重要组成部分，从发电到气候控制。其高效的热量转移能力有助于各个行业的能源节约和可持续发展努力。随着技术的不断进步，核心辅助热交换器的角色可能会在我们追求高效能源使用和环境责任的过程中变得更加关键。