| 1,344 | 9 | 87 |
| 下载次数 | 被引频次 | 阅读次数 |
建立5 mm管径翅片管式换热器百叶窗翅片的物理模型和数学模型,模拟分析百叶窗翅片开窗角度和换热器管间距对空气侧性能的影响,结果表明:在相同迎面风速下,空气侧的换热量及表面传热系数均随百叶窗开窗角度的增大而增大,风机功率随之大幅增加;空气侧的换热量及表面传热系数均随管间距的减小而增大;综合考虑换热量、风机功率及空气侧表面传热系数,开窗角度20°、管间距17.1 mm时换热器空气侧性能更优。
Abstract:The physical and mathematical models of the louvre fins of a 5 mm diameter finned tube heat exchanger are established to simulate and analyze the effects of the slit angle of louvre fins and the tube spacing of heat exchanger on the air-side performa-nce. The results show that under the same facing wind speed, the heat transfer capacity and surface heat transfer coefficient at the air side both increase with the increase of the slit angle, and subsequently, the fan power increases substantially. The heat transfer capacity and surface heat transfer coefficient at the air side both increase with the decrease of the tube spacing. Considering the heat transfer capacity, fan power and air-side surface heat transfer coefficient, the air-side performance of the heat exchanger is optimal with slit angle of 20° and tube spacing of 17.1 mm.
[1] 马国远,高磊,刘帅领,等.制冷空调用换热器研究进展[J].制冷与空调,2023,23(4):88-100.
[2] 中国国家标准化管理委员会.转速可控型房间空调器能效限定值及能效等级:GB 21455—2019[S].北京:中国标准出版社,2019.
[3] 郭梦茹,蔡姗姗,陈焕新,等.翅片管式冷凝器性能分析及多目标优化[J].制冷与空调,2018,18(4):93-98.
[4] 马迪,谭裕锋,吕根贵,等.房间空调器小管径室外换热器流路优化[J].西安交通大学学报,2024,58(5):179-189.
[5] 余鑫泉,盛健,张华,等.空调用翅片管式换热器腐蚀及防护研究进展[J].制冷学报,2022,43(1):1-10.
[6] 朱传辉,李保国,杨会芳.微通道换热器研究及应用进展[J].热能动力工程,2020,35(9):1-9.
[7] 靳自霞.翅片管式换热器百叶窗结构参数优化[J].制冷与空调,2023,23(7):9-13,17.
[8] 丁国良.制冷空调用换热器的高效传热技术[J].制冷与空调,2023,23(4):57-66.
[9] WU G M,YU B,REN T,et al.Modeling and experimental investigation on comprehensive performance of perforated wavy fins for heat pump type air conditioners at frosting and non-frosting conditions[J].Energy and Buildings,2020,225:110342.
[10] 李璐璐,刘中良,李艳霞,等.不同翅片类型对换热器性能影响的模拟计算[J].节能,2020,39(6):62-65.
[11] 朱珊云,戴源德,曹杰,等.小管径开缝翅片管式换热器空气侧传热综合性能研究[J].流体机械,2022,50(5):68-75.
[12] DU Y J,WANG C C.An experimental study of the airside performance of the superslit fin-and-tube heat exchangers[J].International Journal of Heat and Mass Transfer,2000,43(24):4475-4482.
[13] YAN W M,SHEEN P J.Heat transfer and friction characteristics of fin-and-tube heat exchangers[J].International Journal of Heat and Mass Transfer,2000,43(9):1651-1659.
[14] KONG Y Q,YANG L J,DU X Z,et al.Air-side flow and heat transfer characteristics of flat and slotted finned tube bundles with various tube pitches[J].International Journal of Heat and Mass Transfer,2016,99:357-371.
[15] EREK A,ZERDEM B,BILIR L,et al.Effect of geometrical parameters on heat transfer and pressure drop characteristics of plate fin and tube heat exchangers[J].Applied Thermal Engineering,2005,25(14-15):2421-2431.
[16] LIU X Q,WANG M,LIU H H,et al.Numerical analysis on heat transfer enhancement of wavy fin-tube heat exchangers for air-conditioning applications[J].Applied Thermal Engineering,2021,199:117597.
[17] 陶文铨.传热学[M].北京:高等教育出版社,2019:470-472.
[18] WONGWISES S,CHOKEMAN Y.Effect of fin pitch and number of tube rows on the air side performance of herringbone wavy fin and tube heat exchangers[J].Energy Conversion and Management,2005,46(13-14):2216-2231.
[19] WANG C C,LEE C J,CHANG C T,et al.Heat transfer and friction correlation for compact louvered fin-and-tube heat exchangers[J].International Journal of Heat and Mass Transfer,1999,42(11):1945-1956.
[20] 刘妮,李欢,单小丰,等.百叶窗翅片管换热器空气侧传热和流动特性数值模拟[J].热能动力工程,2021,36(6):70-77.
基本信息:
中图分类号:TK172;TM925.12
引用信息:
[1]谭裕锋,刘小琴,马迪,等.翅片管式换热器翅片结构对空气侧性能的影响[J].制冷与空调,2024,24(10):79-84+96.
2024-11-13
2024-11-13
2024-11-13