微流控芯片模芯的精密铣磨加工及其微注塑成形技术

doi:10.3901/JME.2022.01.244

机械工程学报 ›› 2022, Vol. 58 ›› Issue (1): 244-255.doi: 10.3901/JME.2022.01.244

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微流控芯片模芯的精密铣磨加工及其微注塑成形技术

鲁艳军, 刘博, 陈福民, 郭明荣, 唐恒, 罗和喜

深圳大学机电与控制工程学院深圳 518060

收稿日期:2021-05-28 修回日期:2021-09-18 出版日期:2022-01-05 发布日期:2022-03-19
通讯作者: 唐恒(通信作者),男,1989年出生,博士,副研究员,硕士生导师。主要研究方向为表面功能结构制造、微结构制造。E-mail:tangheng@szu.edu.cn
作者简介:鲁艳军,男,1987年出生,博士,助理教授,硕士研究生导师。主要研究方向为精密/超精密加工、磨削加工、微纳结构加工及应用。E-mail:luyanjun@szu.edu.cn,luyanjun_szu@163.com;刘博,男,1996年出生,硕士研究生。主要研究方向为精密磨削加工。E-mail:1900291007@email.szu.edu.cn
基金资助:
国家自然科学基金（51805334）、深圳市国际科技合作（GJHZ20190822091805371）、广东省公益研究与能力建设专项（2017A010102003）和中国台北科技大学与深圳大学学术合作专题（2020002）资助项目。

Precision Milling and Grinding of Mold Core for Microfluidic Chip and its Micro-injection Molding Technology

LU Yanjun, LIU Bo, CHEN Fumin, GUO Mingrong, TANG Heng, LUO Hexi

College of Mechatronics and Control Engineering, Shenzhen University, Shenzhen 518060

Received:2021-05-28 Revised:2021-09-18 Online:2022-01-05 Published:2022-03-19

摘要/Abstract

摘要： 为降低微流控芯片的大批量生产制造成本，保证微尺度流道结构的表面质量和形状精度，提出采用超硬立方氮化硼（CBN）磨棒在模具钢模芯表面精密铣磨加工制造出形状精度可控的微凸起阵列结构，然后利用微注塑成形技术高效成形制造出具有微凹槽阵列结构的聚合物微流控芯片。分析了铣磨加工工艺参数对微结构模芯表面质量的影响，通过试验和数学统计理论分析法研究了微注塑成形工艺参数对微结构聚合物表面粗糙度和形状精度的作用机制以及影响程度。试验结果表明：较优的铣磨工艺参数为主轴转速16 000 r/min，切削深度2 μm和进给速率15 mm/min，此时微结构模芯的表面粗糙度Ra达到0.299 μm。熔体温度和保压时间对聚合物微流道形状精度PV和底部粗糙度Ra的影响较大，保压压力次之，注射速度则最小。当熔体温度、注射速度、保压压力和保压时间分别为235℃，80 mm/s，5 MPa和9 s时，微流道形状精度达到8.950 μm，微流道底部粗糙度Ra为0.055 μm。

关键词: 微流控芯片, 铣磨加工, 微注塑成形, 表面粗糙度, 形状精度

Abstract: In order to reduce the mass production and manufacturing cost of microfluidic chips and ensure the surface quality and form accuracy of the micro-scale flow channel structures, a superhard cubic boron nitride (CBN) grinding tool is proposed to precisely mill and grind the surface of die steel core to produce the micro convex array structures with controllable form accuracy, and then the polymeric microfluidic chip with micro groove array structures can be efficiently formed by micro injection molding technology. The influences of the milling-grinding process parameters on the surface quality of the micro-structured mold core are analyzed, and the effects of the micro injection molding process parameters on the surface roughness and from accuracy of the micro-structured polymer are investigated and analyzed through the experimental and theoretical mathematical statistics methods. The experimental results show that the more optimal milling-grinding process parameters including the spindle speed, cutting depth and feed rate are 16 000 r/min, 2 μm and 15 mm/min, respectively. Meanwhile, the surface roughness Ra of micro-structured mold core is 0.299 μm. The melt temperature and holding time have great influences on form accuracy PV and bottom surface roughness Ra, followed by holding pressure and injection speed. When the melt temperature, injection speed, holding pressure and holding time are 235℃, 80 mm/s, 5 MPa and 9 s, respectively, the form accuracy of micro-channel reaches 8.950 μm and the surface roughness Ra of micro-channel bottom is 0.055 μm.

Key words: microfluidic chip, milling-grinding machining, micro injection molding, surface roughness, form accuracy

中图分类号:

TH16

鲁艳军, 刘博, 陈福民, 郭明荣, 唐恒, 罗和喜. 微流控芯片模芯的精密铣磨加工及其微注塑成形技术[J]. 机械工程学报, 2022, 58(1): 244-255.

LU Yanjun, LIU Bo, CHEN Fumin, GUO Mingrong, TANG Heng, LUO Hexi. Precision Milling and Grinding of Mold Core for Microfluidic Chip and its Micro-injection Molding Technology[J]. Journal of Mechanical Engineering, 2022, 58(1): 244-255.

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微流控芯片模芯的精密铣磨加工及其微注塑成形技术

Precision Milling and Grinding of Mold Core for Microfluidic Chip and its Micro-injection Molding Technology

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