飞溅填充型自然通风混合式(湿/干)冷却塔的实验研究

IF 1.8 Q4 ENERGY & FUELS
AIMS Energy Pub Date : 2022-01-01 DOI:10.3934/energy.2022031
Abdellateef Khalifa Hamid Ali, Ahmed Qassem Mohammed, Q. Mahdi
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引用次数: 0

摘要

冷却塔对工作和效率有如此重大的影响,研究人员和设计师正在不知疲倦地努力提高它们的性能。自然通风混合式(干湿式)冷却塔的原型设计基于几何、动力学和热力学的相似性。根据伊拉克的天气,在夏季(炎热和干燥)天气条件下使用飞溅填充(150毫米)进行了试验。本研究研究了自然通风混合式冷却塔模型(NDHCTs)中空气和水的直接(湿段)和间接(干段)换热机制。该塔充满了飞溅式填料,温水通过喷雾器在整个建筑中扩散。研究了水流量、填料厚度、风速对冷却塔冷却范围、冷却方式、制冷量、冷却塔热效率、气流中水分蒸发损失和失水率的影响。实验采用了四种不同的水流速度,从每分钟7.5升到每分钟12升,以及八种不同的风速,同时保持恒定的进水温度和零侧风(m/s)。已经收集了数据,并确定了性能变量。结果表明:冷却塔的效率在低水流量时提高,冷却范围随风速的增大而增大,随水流量的增大而减小;在7.5 Lpm的水流量和2.4 m/s的风速下,膨胀至19.5℃。当水流量为12lpm,风速为2.4 m/s时,制冷量增加到23.2 kW。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Experimental study of a natural draft hybrid (wet/dry) cooling tower with a splash fill type
Cooling towers have such a significant influence on work and efficiency that researchers and designers are working tirelessly to enhance their performance. A prototype design for a natural draft hybrid (wet/dry) cooling tower has been created, relying on geometrical, dynamic, and thermodynamic similarities. Based on Iraqi weather, experiments have been conducted using splash fill (150 mm) in summer (hot and dry) weather conditions. This study investigated heat transfer mechanisms of both air and water in a natural draft hybrid cooling tower model(NDHCTs), both directly (wet section) and indirectly (dry section). The tower is filled with splash-style packing, and the warm water is spread throughout the building using sprayer nozzles. The influences of water flow rates, fill thickness, and air velocity on the cooling range, approach, cooling capacity, thermal efficiency of the cooling tower, water evaporation loss into the air stream and water loss percentage were explored in this study. The experimental were carried out with four different water flow rates, ranging from 7.5 to 12 (Lpm) litres per minute, and eight different air velocities, all while keeping a constant inlet water temperature and a zero (m/s) crosswind. Data has been gathered, and performance variables have been determined. The findings demonstrate that the cooling tower's efficacy increases when the water flow rate is low, and the cooling range increases with increasing air velocity and decreases with increasing water flow rate; for a 7.5 Lpm water flow rate and a 2.4 m/s air velocity, it expanded to 19.5 ℃. The cooling capacity increased to 23.2 kW for a water flow rate of 12 Lpm and an air velocity of 2.4 m/s.
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来源期刊
AIMS Energy
AIMS Energy ENERGY & FUELS-
CiteScore
3.80
自引率
11.10%
发文量
34
审稿时长
12 weeks
期刊介绍: AIMS Energy is an international Open Access journal devoted to publishing peer-reviewed, high quality, original papers in the field of Energy technology and science. We publish the following article types: original research articles, reviews, editorials, letters, and conference reports. AIMS Energy welcomes, but not limited to, the papers from the following topics: · Alternative energy · Bioenergy · Biofuel · Energy conversion · Energy conservation · Energy transformation · Future energy development · Green energy · Power harvesting · Renewable energy
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