基于Minitab软件的速冻机内圆漏斗喷嘴结构优化  

作　　者：谢晶[1,2,3,4] 郭珍权 柳雨嫣 王金锋 杨晓燕[5] 刘彦岑 XIE Jing;GUO Zhenquan;LIU Yuyan;WANG Jinfeng;YANG Xiaoyan;LIU Yancen(College of Food Science and Technology,Shanghai Ocean University,Shanghai 201306,China;Shanghai ProfessionalTechnology Service Platform on Cold Chain Equipment Performance and Energy Saving Evaluation,Shanghai 201306,China;National Experimental Teaching Demonstration Center for Food Science and Engineering(Shanghai Ocean University),Shanghai 201306,China;Shanghai Engineering Research Center of Aquatic Product Processing&Preservation,Shanghai201306,China;Square Technology Group Co.,Ltd.,Nantong 226371,Jiangsu,China)

机构地区：[1]上海海洋大学食品学院,上海201306 [2]上海冷链装备性能与节能评价专业技术服务平台,上海201306 [3]食品科学与工程国家级实验教学示范中心(上海海洋大学),上海201306 [4]上海水产品加工及贮藏工程技术研究中心,上海201306 [5]四方科技集团有限公司,江苏南通226371

出　　处：《上海海洋大学学报》2023年第6期1099-1108,共10页Journal of Shanghai Ocean University

基　　金：国家“十三五”重点研发项目(2016YFD0400303);上海市科学技术委员会平台能力建设项目(16DZ2280300);上海市科学技术委员会公共服务平台建设项目(17DZ2293400)。

摘　　要：为了增强冲击式速冻机内的传热强度和均匀性,本文以冲击式速冻机试验台为依托,提出了一种新型喷嘴结构——圆漏斗喷嘴。在该试验台被试验验证可靠的基础上,利用数值模拟技术对该试验台流场进行了模拟计算,利用Minitab软件中的Plackett-Burman设计从圆漏斗喷嘴出口直径D_(E)、漏斗宽度L_(3)、漏斗高度L_(1)、射流高度L_(2)、喷嘴排数N、喷嘴间隙S和喷嘴到钢带的距离H等7个因素中得到漏斗宽度、射流高度和喷嘴排数等3个因素为影响钢带表面努塞尔数和传热均匀度的显著性因素,然后利用Box-Behnken设计,建立3个显著性因素与钢带表面平均努塞尔数Nu_(ave)和传热均匀指标η等2个响应值之间的数学模型,确定喷嘴最佳的结构参数。结果表明:最佳结果参数为漏斗宽度17 mm、射流高度50 mm、喷嘴排数为3;在此条件下钢带表面Nu_(ave)为448.68、传热均匀指标为0.232 9,通过数值模拟得到的值与方程预测值总体吻合,说明优化得到的圆漏斗喷嘴的新型结构参数能够使速冻机的速冻效率达到最佳。In order to enhance the heat transfer intensity and uniformity in an air impinging freezer,an impinging freezing experimental table was designed as the research object,and a new nozzle structure—circular funnel nozzle was proposed.The numerical simulation technology was used to simulate the flow fields in the impinging freezing experimental table,which was testified by experiments.The flow medium was air,and the simulation process assumes:(1) The wall of static pressure chamber was adiabatic.(2) Air was an incompressible,homogeneous viscous fluid.(3) During the normal operation,the internal flow field of the model was regarded as steady state.The three-dimensional continuity equation,the momentum equation,the energy equation,the kinetic energy k equation and the turbulent dissipation ε equation were used.The cooling air inlet and outlet pressure were 250 Pa(P_(in)) and 0 Pa(P_(out)) respectively.For the frozen area,the cooling air inlet and outlet temperature was 230 K and 235 K.The mass flow rate at the cooling air inlet is0.064 4 kg/s.The thermal conductivity of steel strip was 16.3 W/(m·℃).Using the Plackett-Burman design,the significant factors for the average Nusselt number on the steel strip surface were obtained from the factors of outlet diameter D_E,funnel width L_3,funnel height L_1,jet height L_2,nozzle number N,nozzle spacing S and nozzle-to-surface distance H.These significant factors were funnel width L_3,jet height L_(2) and nozzle number N.The others had little effect on the average Nusselt number.So in the next study,these factors adopted the median values.Then,using the Box-Behnken design,a mathematical model between those three significant factors and the two response values which were average Nusselt number Nu_(ave) and the heat transfer uniformity index η on the steel strip surface was established to determine the optimal structural parameters.The F value in the regression equation can be used to determine the influence of the factors on the response value.Therefore,the order of the fa

关 键 词：速冻机 喷嘴 努塞尔数 传热均匀度 结构优化 

分 类 号：TH122[机械工程—机械设计及理论]