螺旋搅拌混合机颗粒混合工艺参数优化研究
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摘要
为降低螺旋搅拌混合机工作能耗,提高混合工作效率,该文采用离散元法对糙米颗粒在搅拌仓内的混合特性进行模拟研究,分析了螺旋搅拌混合机转速和填充率对混合程度与能耗的影响,并应用SigmaPlot软件分析处理数据,应用1stOpt软件采用麦夸特法与通用全局优化法拟合填充率与能耗的数学关系,并建立了能耗模型。结果表明:颗粒的混合均匀是在扩散运动、同向运动、交叉运动、剪切运动的共同作用下完成的;随着转速的增长,颗粒混合均匀所需时间减少,终了混合度增加,且90 r/min时所需能耗最少;填充率越小,颗粒混合速度越快,并随着填充率的提高能耗增加,建立的数学模型能准确表征填充率与能耗的关系。研究结果可为糙米螺旋搅拌机工艺参数优化提供理论依据,也为其他颗粒工艺参数优化提供参考。
In order to reduce the energy consumption and improve the mixing efficiency of the screw mixer, in this paper, the mixing characteristics of brown rice particles in the mixing bin were simulated by the discrete element method, and the effects of the rotational speed and filling rate of the screw mixer on the mixing degree and energy consumption were analyzed. The data were analyzed and processed by SigmaPlot software, Using 1 stOpt software, the mathematical relationship between filling rate and energy consumption was fitted by Levenberg-Marquardt and general global optimization method, and the energy consumption model was established. The results showed that the mixing uniformity of particles is accomplished under the combined action of diffusion motion, co-direction motion, crisscross motion and shear motion; With the increase of rotational speed, the time required for uniform particle mixing decreases, the final mixing degree increases, and the energy consumption is minimum at 90 r/min; The smaller the filling rate, the faster the particle mixing speed. With the increase of filling rate, the energy consumption increases. The mathematical model can accurately characterize the relationship between filling rate and energy consumption. The research results can provide theoretical basis for the optimization of technological parameters of brown rice spiral mixer, and also provide reference for the optimization of other granular technological parameters.
In order to reduce the energy consumption and improve the mixing efficiency of the screw mixer, in this paper, the mixing characteristics of brown rice particles in the mixing bin were simulated by the discrete element method, and the effects of the rotational speed and filling rate of the screw mixer on the mixing degree and energy consumption were analyzed. The data were analyzed and processed by SigmaPlot software, Using 1 stOpt software, the mathematical relationship between filling rate and energy consumption was fitted by Levenberg-Marquardt and general global optimization method, and the energy consumption model was established. The results showed that the mixing uniformity of particles is accomplished under the combined action of diffusion motion, co-direction motion, crisscross motion and shear motion; With the increase of rotational speed, the time required for uniform particle mixing decreases, the final mixing degree increases, and the energy consumption is minimum at 90 r/min; The smaller the filling rate, the faster the particle mixing speed. With the increase of filling rate, the energy consumption increases. The mathematical model can accurately characterize the relationship between filling rate and energy consumption. The research results can provide theoretical basis for the optimization of technological parameters of brown rice spiral mixer, and also provide reference for the optimization of other granular technological parameters.
引文
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[11]左彦军,贾富国,夏吉庆.逆流式糙米加湿调质机技术参数对加湿均匀性的影响[J].农业工程学报,2009,25(5):123-126.
[12]李世伟,王鹏程,王正宏,等.基于离散元方法的RDX-Al颗粒混合数值模拟分析[J].爆破器材,2017,46(5):13-17.
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[14]刘文亮,刘扬,张永成,等.U型混合机内颗粒混合运动的离散元模拟[J].饲料工业,2019,40(3):10-14.
[15]刘扬,韩燕龙,贾富国,等.椭球颗粒搅拌运动及混合特性的数值模拟研究[J].物理学报,2015,64(11):258-265.
[16]张凯杰,许蔷,王滔.基于三维离散法翻转混合设备颗粒的运动行为模拟研究[J].食品与机械,2018,34(2):88-92.
[17]周基,田琼,芮勇勤,等.基于数字图像的沥青混合料离散元几何建模方法[J].土木建筑与环境工程,2012,34(1):136-140.
[18]刘扬,曹昕昕,兰海鹏,等.搅拌工艺参数对糙米混合特性影响的数值模拟[J].江苏农业科学,2017,45(15):214-217.
[19]陈志平,章序文,林兴华.搅拌与混合设备设计选用手册[M].北京:化学工业出版社,2004.
[2]欧阳鸿武,黄誓成,彭政,等.颗粒物质的堵塞行为[J].粉末冶金材料科学与工程,2008,13(5):260-268.
[3]欧阳鸿武,黄誓成,刘卓民,等.颗粒物质的堵塞行为与非晶相变[J].稀有金属材料与工程,2009,38(7):1310-1316.
[4]欧阳鸿武,黄立华,程亮,等.低速转鼓中颗粒流态的滞后转变行为[J].粉末冶金材料科学与工程,2013,18(2):155-162.
[5]赵永志,江茂强,郑津洋.巴西果效应分离过程的计算颗粒力学模拟研究[J].物理学报,2009,58(3):1812-1818.
[6]高红利,陈友川,赵永志,等.薄滚筒内二元湿颗粒体系混合行为的离散单元模拟研究[J].物理学报,2011,60(12):330-337.
[7]赵啦啦,赵跃民,刘初升,等.湿颗粒堆力学特性的离散元法模拟研究[J].物理学报,2014,63(3):265-273.
[8]M.Lemieux,F.Bertrand,et al.Comparative study of the mixing of free-flowing particles in a V-blender and a bin-blender[J].Chemical Engineering Science,2007,62:1783-1802.
[9]Paul W Cleary,Matthew D Sinnott.Assessing mixing characteristics of particle-mixing and granulation devices[J].Particuology,2008,6:419-444.
[10]江茂强.双锥型混合机内颗粒混合及增混机理研究[D].杭州:浙江大学,2010:20-54.
[11]左彦军,贾富国,夏吉庆.逆流式糙米加湿调质机技术参数对加湿均匀性的影响[J].农业工程学报,2009,25(5):123-126.
[12]李世伟,王鹏程,王正宏,等.基于离散元方法的RDX-Al颗粒混合数值模拟分析[J].爆破器材,2017,46(5):13-17.
[13]陶宇浩.基于离散元方法的颗粒混合数值模拟分析[D].南京理工大学,2015.
[14]刘文亮,刘扬,张永成,等.U型混合机内颗粒混合运动的离散元模拟[J].饲料工业,2019,40(3):10-14.
[15]刘扬,韩燕龙,贾富国,等.椭球颗粒搅拌运动及混合特性的数值模拟研究[J].物理学报,2015,64(11):258-265.
[16]张凯杰,许蔷,王滔.基于三维离散法翻转混合设备颗粒的运动行为模拟研究[J].食品与机械,2018,34(2):88-92.
[17]周基,田琼,芮勇勤,等.基于数字图像的沥青混合料离散元几何建模方法[J].土木建筑与环境工程,2012,34(1):136-140.
[18]刘扬,曹昕昕,兰海鹏,等.搅拌工艺参数对糙米混合特性影响的数值模拟[J].江苏农业科学,2017,45(15):214-217.
[19]陈志平,章序文,林兴华.搅拌与混合设备设计选用手册[M].北京:化学工业出版社,2004.
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