化工进展
化工進展
화공진전
CHEMICAL INDUSTRY AND ENGINEERING PROGRESS
2014年
8期
2144-2149
,共6页
原玫%巨晓洁%谢锐%汪伟%褚良银
原玫%巨曉潔%謝銳%汪偉%褚良銀
원매%거효길%사예%왕위%저량은
聚(N-异丙基丙烯酰胺)%锂藻土%纳米复合凝胶微球%杨氏模量%弹性力学性能
聚(N-異丙基丙烯酰胺)%鋰藻土%納米複閤凝膠微毬%楊氏模量%彈性力學性能
취(N-이병기병희선알)%리조토%납미복합응효미구%양씨모량%탄성역학성능
poly(N-isopropylacrylamide)%Laponite%nanocomposite hydrogel microspheres%Young’s modulus%elastic mechanical properties
利用微流控技术,以锂藻土作为交联剂,成功制备得到温度响应型聚(N-异丙基丙烯酰胺)(PNIPAM)与锂藻土的纳米复合凝胶微球,并利用一种简单的微步进单轴压缩装置,分别在25℃和37℃下对具有不同锂藻土含量的 PNIPAM/锂藻土纳米复合凝胶微球的弹性力学性能进行系统研究。该微步进单轴压缩装置主要包括三个部分:一个程控进样器用以实现对凝胶微球的微步进压缩,一套配有高分辨率数码相机的侧视光学系统用以记录凝胶微球受压时发生的形变,一台精密电子天平作为力传感器用来记录凝胶微球在特定形变下所受的外力。研究结果表明,纳米复合凝胶微球在25℃和37℃下的形变量H与所受压力F的实验数据与Hertz弹性接触理论方程呈现良好的拟合关系,证明了PNIPAM/锂藻土纳米复合凝胶微球在25℃和37℃下均具有弹性形变行为。同时,随着锂藻土含量的增加,PNIPAM/锂藻土纳米复合凝胶微球的温敏性降低,但其杨氏模量增大。具有相同锂藻土含量的纳米复合凝胶微球,由于温度升高凝胶体积收缩、凝胶结构变得致密,因此在37℃下的杨氏模量大于其在25℃下的杨氏模量。研究结果可为PNIPAM/锂藻土纳米复合凝胶微球的设计与实际应用提供指导。
利用微流控技術,以鋰藻土作為交聯劑,成功製備得到溫度響應型聚(N-異丙基丙烯酰胺)(PNIPAM)與鋰藻土的納米複閤凝膠微毬,併利用一種簡單的微步進單軸壓縮裝置,分彆在25℃和37℃下對具有不同鋰藻土含量的 PNIPAM/鋰藻土納米複閤凝膠微毬的彈性力學性能進行繫統研究。該微步進單軸壓縮裝置主要包括三箇部分:一箇程控進樣器用以實現對凝膠微毬的微步進壓縮,一套配有高分辨率數碼相機的側視光學繫統用以記錄凝膠微毬受壓時髮生的形變,一檯精密電子天平作為力傳感器用來記錄凝膠微毬在特定形變下所受的外力。研究結果錶明,納米複閤凝膠微毬在25℃和37℃下的形變量H與所受壓力F的實驗數據與Hertz彈性接觸理論方程呈現良好的擬閤關繫,證明瞭PNIPAM/鋰藻土納米複閤凝膠微毬在25℃和37℃下均具有彈性形變行為。同時,隨著鋰藻土含量的增加,PNIPAM/鋰藻土納米複閤凝膠微毬的溫敏性降低,但其楊氏模量增大。具有相同鋰藻土含量的納米複閤凝膠微毬,由于溫度升高凝膠體積收縮、凝膠結構變得緻密,因此在37℃下的楊氏模量大于其在25℃下的楊氏模量。研究結果可為PNIPAM/鋰藻土納米複閤凝膠微毬的設計與實際應用提供指導。
이용미류공기술,이리조토작위교련제,성공제비득도온도향응형취(N-이병기병희선알)(PNIPAM)여리조토적납미복합응효미구,병이용일충간단적미보진단축압축장치,분별재25℃화37℃하대구유불동리조토함량적 PNIPAM/리조토납미복합응효미구적탄성역학성능진행계통연구。해미보진단축압축장치주요포괄삼개부분:일개정공진양기용이실현대응효미구적미보진압축,일투배유고분변솔수마상궤적측시광학계통용이기록응효미구수압시발생적형변,일태정밀전자천평작위력전감기용래기록응효미구재특정형변하소수적외력。연구결과표명,납미복합응효미구재25℃화37℃하적형변량H여소수압력F적실험수거여Hertz탄성접촉이론방정정현량호적의합관계,증명료PNIPAM/리조토납미복합응효미구재25℃화37℃하균구유탄성형변행위。동시,수착리조토함량적증가,PNIPAM/리조토납미복합응효미구적온민성강저,단기양씨모량증대。구유상동리조토함량적납미복합응효미구,유우온도승고응효체적수축、응효결구변득치밀,인차재37℃하적양씨모량대우기재25℃하적양씨모량。연구결과가위PNIPAM/리조토납미복합응효미구적설계여실제응용제공지도。
Temperature-responsive poly(N-isopropylacrylamide) (PNIPAM) nanocomposite hydrogel microspheres are successfully prepared by microfluidic technology using Laponite as crosslinker in this work. A simple micro-step uniaxial compression device is developed to study the elastic properties of PNIPAM/Laponite nanocomposite hydrogel microspheres,which only needs a programmed syringe to achieve the micro-compression deformation and a precision electronic balance to measure the applied force. The images of compression process of a single hydrogel microsphere are captured by a side-view optical system. The results show that PNIPAM/Laponite nanocomposite hydrogel microspheres exhibit elastic deformation at both 25℃ and 37℃,and the obtained force-deformation experimental data fit well with the Hertz Theory. The Laponite content in the nanocomposite hydrogel microspheres significantly affects their mechanical properties and temperature-responsive behaviors. With the increase of Laponite content,the thermo-responsive volume change degree of the nanocomposite hydrogel microspheres decreases. But the Young’s modulus of PNIPAM/Laponite nanocomposite hydrogel microspheres increases with the increase of the Laponite content at both 25℃ and 37℃. Furthermore,the Young’s modulus of PNIPAM/Laponite nanocomposite hydrogel microspheres at 37℃ is much larger than that at 25℃ due to the thermo-induced volume shrinkage and rigidity increase. The results in this study provide a valuable guidance for designing smart hydrogel microspheres for practical applications.
