化工学报
化工學報
화공학보
JOURNAL OF CHEMICAL INDUSY AND ENGINEERING (CHINA)
2014年
9期
3654-3660
,共7页
刘超鹏%巫江虹%黄一鹤%唐永柏
劉超鵬%巫江虹%黃一鶴%唐永柏
류초붕%무강홍%황일학%당영백
磁制冷%能效评价%传热%实验验证
磁製冷%能效評價%傳熱%實驗驗證
자제랭%능효평개%전열%실험험증
magnetic refrigeration%exergy%energy efficiency evaluation%heat transfer%experimental validation
为建立磁制冷机能效统一评价指标,弥补采用温跨和制冷量作为磁制冷系统性能评价标准的不足,在现有评价方法的基础上提出了新的室温磁制冷样机能效指标-?效率。为了验证新评价指标的可行性,分别对2011年维多利亚大学公布的样机数据和2012年丹麦理工大学公布的样机数据进行分析计算,将以温跨-热源温度和温跨-制冷量形式给出的测试数据统一转换为温跨-冷量?的形式,以实现对不同样机的能效进行客观评价;同时搭建测试平台对四川大学旋转式室温磁制冷样机在25、27及30℃工况下进行冷量?、?效率指标测试。实验结果表明,该室温磁制冷样机在25℃工况下,磁制冷机转速6 r·min-1时,制冷量为240 W,最大冷量?为3.26 W。在剔除电机损失、机械损失、磁滞损失及涡流损失等因素的影响后,最大?效率为0.039。
為建立磁製冷機能效統一評價指標,瀰補採用溫跨和製冷量作為磁製冷繫統性能評價標準的不足,在現有評價方法的基礎上提齣瞭新的室溫磁製冷樣機能效指標-?效率。為瞭驗證新評價指標的可行性,分彆對2011年維多利亞大學公佈的樣機數據和2012年丹麥理工大學公佈的樣機數據進行分析計算,將以溫跨-熱源溫度和溫跨-製冷量形式給齣的測試數據統一轉換為溫跨-冷量?的形式,以實現對不同樣機的能效進行客觀評價;同時搭建測試平檯對四川大學鏇轉式室溫磁製冷樣機在25、27及30℃工況下進行冷量?、?效率指標測試。實驗結果錶明,該室溫磁製冷樣機在25℃工況下,磁製冷機轉速6 r·min-1時,製冷量為240 W,最大冷量?為3.26 W。在剔除電機損失、機械損失、磁滯損失及渦流損失等因素的影響後,最大?效率為0.039。
위건립자제랭궤능효통일평개지표,미보채용온과화제랭량작위자제랭계통성능평개표준적불족,재현유평개방법적기출상제출료신적실온자제랭양궤능효지표-?효솔。위료험증신평개지표적가행성,분별대2011년유다리아대학공포적양궤수거화2012년단맥리공대학공포적양궤수거진행분석계산,장이온과-열원온도화온과-제랭량형식급출적측시수거통일전환위온과-랭량?적형식,이실현대불동양궤적능효진행객관평개;동시탑건측시평태대사천대학선전식실온자제랭양궤재25、27급30℃공황하진행랭량?、?효솔지표측시。실험결과표명,해실온자제랭양궤재25℃공황하,자제랭궤전속6 r·min-1시,제랭량위240 W,최대랭량?위3.26 W。재척제전궤손실、궤계손실、자체손실급와류손실등인소적영향후,최대?효솔위0.039。
A novel energy efficiency evaluation index, exergetic efficiency, was proposed to evaluate the performance of magnetic refrigerator rationally and compensate for the limitation in evaluating magnetic refrigerator system with available two indexes, temperature span and cooling capacity. To testify the feasibility of exergetic efficiency evaluation indexes, the experimental data by University of Victoria in the form of temperature span-heat source temperature curve and experimental data by Technical University of Denmark in the form of temperature span-cooling capacity curve were converted to the temperature span-exergetic cooling capacities. Furthermore an experimental platform was established based on Sichuan University magnetic refrigerator prototype. With the heat source temperature controlled at 25, 27 and 30℃, performance parameters of refrigerator such as cooling capacity, temperature span, cooling exergy and exergetic efficiency were obtained. Experimental results indicated that the cooling capacity of the magnetic refrigerator prototype could reach 240 W and its maximum cooling exergy was 3.26 W at heat source temperature 30℃ and 6 r·min-1. With the efficiencies of motor loss, mechanical loss, hysteretic loss and eddy current loss ignored, the peak exergetic efficiency was 0.039.
