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聚合物微流控芯片超声波微熔融键合方法 被引量:2

Ultrasonic Micro-Melting Bonding Method of Polymer Microfluidic Chips
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摘要 为了将超声波聚合物焊接技术更好地应用于聚合物微流控芯片的键合,提出基于界面微熔融的聚合物微流控芯片超声波键合方法.设计了适用于该方法的导能筋结构,在合理的键合工艺参数控制下使导能筋结构材料不发生熔融流延,通过键合界面软化润湿来实现对微流控芯片微通道的密封连接.实验结果表明,键合时间仅为0.09 s,键合后微通道的承压能力可达6个大气压,满足微流控芯片的使用要求.面接触导能筋可采用机械加工或注塑方法获得,具有良好的产业化应用前景. In order to better apply ultrasonic polymer welding technology to the bonding of polymer microfluidic chips,a surface micro-melting ultrasonic bonding method was proposed.The area contact energy director for the proposed method was designed and with reasonable control of the bonding parameters,the melting material of the area contact energy director did not flow in the bonding process.The interface of the two polymer substrates was softened and moistened by ultrasonic energy,so that the microchannel of the microfluidic chips was sealed and bonded.Experimental results show that it takes only 0.09 s to achieve the whole ultrasonic bonding and the resistance of the microchannel to pressure reaches 6 atmospheres,which meets the requirement for microfluidic chips' application.The area contact energy directors can be made by machining or injection molding,showing a good prospect of industrialization of microfluidic chips.
作者 王晓东 郑英松 张宗波 罗怡
机构地区 大连理工大学精密与特种加工教育部重点实验室 辽宁省微纳米技术及系统重点实验室
出处 《纳米技术与精密工程》 EI CAS CSCD 2011年第3期270-274,共5页 Nanotechnology and Precision Engineering
基金 国家自然科学基金资助项目(50775024) 教育部新世纪优秀人才支持计划资助项目(NCET-06-0279)
关键词 微熔融 超声波键合 面接触导能筋 微通道 micro-melting ultrasonic bonding area contact energy director microchannel
分类号 TN405 [电子电信—微电子学与固体电子学]
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二级参考文献76

共引文献26

同被引文献16

  • 1韦鹤,王晓东,刘冲,廖俊峰.塑料微流控芯片的超声波焊接键合的仿真[J].中国机械工程,2005,16(z1):82-85. 被引量:5
  • 2WANG X D, JIN J, LI X, et al.. Low pressure thermal bonding [J]. Microelectronic Engineering, 2011, 88 2427-2430.
  • 3LI X, WU N Q, ROJANASAKUL Y, et al.. Se- lective stamp bonding of PDMS microfluidic devices to polymer substrates for biological applications [J]. Sensors and Actuators, 2013, 193..186-192.
  • 4TRUCKENMULLER R, CHENG Y, AHRENS R, et al.. Micro ultrasonic welding:joining of chemically inert polymer microparts for single material fluidic components and systems [J]. Microsystern Technolo- gies , 2006, 12(10-11) :1027-1029.
  • 5罗怡,张苗苗,孙屹博,等.PC微流控芯片黏接筋与溶剂的协同辅助键合[J].光学精密工程,2011,19(4):754761.
  • 6JAKEWAYSC, DEMAJ, RUSSELEL. Mini- aturized total analysis systems for biological analy sis [J]. Fresenius' Journal of Analytical Chemis- try, 2000, 366(6-7) :525 539.
  • 7CHUAH Y K, CHIEN L H J, CHANG B C, et al.. Effects of the shape of the energy director on far-field ultrasonic welding of thermoplastics [J]. Polymer Engineering Science, 2000, 40 ( 1 ) : 157 167.
  • 8JIANG J, ZHAN J, YUE W, et al.. A single low-cost microfabrication approach for polymeth- y|methacrylate, polystyrene, polycarbonate and polysulfone based microdevices [J ]. RSC Ad vances, 2015, 5(45):36036-36043.
  • 9MUKHOPADHYAY S, BANERJEE J P, ROY S S, et al.. Effects of liquid viscosity, surface wet- tability and channel geometry on capillary flow in SU8 based microfluidic devices [J]. International Journal of Adhesion and Adhesives, 2013, 42 .. 30- 35.
  • 10ZIMMERMANN M, SCHMID H, HUNZIKER P, et al.. Capillary pumps for autonomous capil lary systems [J]. Lab on a Chip, 2007, 7(1): 119 125.

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纳米技术与精密工程
2011年 第3期

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