CN104629358B - 一种尼龙1111/聚偏氟乙烯铁电复合薄膜及其制备方法 - Google Patents
一种尼龙1111/聚偏氟乙烯铁电复合薄膜及其制备方法 Download PDFInfo
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Abstract
本发明属于高分子共混复合材料制备领域,公开了一种尼龙1111/聚偏氟乙烯铁电复合薄膜及其制备方法。本发明所述的铁电复合薄膜是由20‑80份尼龙1111和80‑20份聚偏氟乙烯制备而成。其制备方法是先将尼龙1111与聚偏氟乙烯在熔融混炼设备中共混,然后由热压设备热压成薄膜,接着将熔融态薄膜淬火,最后经拉伸设备单轴拉伸得到。所制备的复合薄膜剩余极化强度均要高于纯聚偏氟乙烯薄膜。该法制备方法简单,设备工业常见,容易操作。铁电复合薄膜成本低,有望在压电、热电和铁电材料领域制备器件。
Description
技术领域
本发明属于高分子共混复合材料制备领域,具体涉及一种尼龙与聚偏氟乙烯复合铁电薄膜及其制备方法。
背景技术
铁电材料是指存在自发极化,且其极化方向能随着外加电场的反转而反转的材料。铁电材料同时具有压电、热释电、声光、电光、非线性光学和光折变效应,因而在光电子、微电子和集成光学等领域获得了大量的应用。聚合物铁电材料比铁电陶瓷密度低、柔性高、易大面积成型、可裁剪、介电击穿强度高,在换能器和传感器应用上占有十分独特的地位。聚合物铁电体比较稀少,主要有聚偏氟乙烯及其共聚物和奇数尼龙等。聚偏氟乙烯及其共聚物压电和铁电活性高,是目前唯一能够商业应用的铁电聚合物,但是聚偏氟乙烯价格昂贵。
聚合物共混是降低成本的一种方法。由于活性高的铁电聚合物种类很少,再加上奇数尼龙11比聚偏氟乙烯成本低,有关聚偏氟乙烯共混复合铁电体材料的研究就集中在尼龙11上,如中国专利CN102888102B通过引入离子液体制备了尼龙11/聚偏氟乙烯复合铁电体材料。Yongjin Li等通过挤出法制备了尼龙11/聚偏氟乙烯复合薄片,再辊压得到复合铁电薄膜(参见非专利文献Journal of Polymer Science Part B: Polymer Physics.2007, 45(19): 2707-2714)。奇-奇尼龙是另一类铁电聚合物。非专利文献已经证实奇-奇尼龙1111是活性很高的铁电体(Appl. Phys. Lett., 2014, 104: 172906.)。奇-奇尼龙1111的物理机械性能与尼龙11相近。同时,用石油炼制的副产物轻蜡经微生物发酵得到十一碳二元胺为主要原料制备尼龙1111合成步骤少,生产周期短,条件温和,成本比尼龙11还要低很多(中国专利CN1184251C)。因此,奇-奇尼龙1111与聚偏氟乙烯复合能降低聚偏氟乙烯的成本。然而迄今为止,奇-奇尼龙与聚偏氟乙烯复合制备铁电材料未有文献报道。
发明内容
本发明目的是提供一种成本低、性能优异的奇-奇尼龙1111/聚偏氟乙烯复合铁电薄膜,并且提供一种简单易行的制备方法。
为实现本发明的目的,采用以下技术方案来实现:
本发明所述奇-奇尼龙1111/聚偏氟乙烯复合铁电薄膜,由一定质量的尼龙1111与聚偏氟乙烯为原料制备而成,其制备工艺包括:原料烘干、熔融共混、热压和单轴拉伸等步骤。
进一步优选包括以下步骤:
(1)称量原料尼龙1111与聚偏氟乙烯,尼龙1111与聚偏氟乙烯重量份为20~80份和80~20份,于80~100℃真空干燥。
(2)将干燥后的原料混合,在熔融混炼设备上共混,温度200~240℃,得到尼龙1111/聚偏氟乙烯共混物。
(3)将尼龙1111/聚偏氟乙烯共混物用铝箔包裹在热压设备上热压成厚度为30~50微米薄膜,热压温度210~230℃。
(4)将处在熔融状态的薄膜迅速在冰水混合物或冰盐水中淬火,得到淬火薄膜。
(5)强碱溶液溶解淬火薄膜两面的铝箔得到初始薄膜,自然干燥。
(6)初始薄膜在拉力机上拉伸,拉伸温度20~100℃,拉伸比n为0.5~5,得到厚度10~30微米的铁电复合薄膜。
所述步骤(2)熔融混炼设备包括哈克(Haake)转矩流变仪、双螺杆挤出机、密炼机、开炼机等熔融混炼设备。
所述步骤(3)的压力机包括热压机、硫化机等工业常见热压设备。
所述步骤(5)的强碱溶液为氢氧化钠和氢氧化钾,溶液质量浓度范围5%~30%。溶解时的温度优选保持在30℃以下。
所述步骤(6)拉伸比n是指拉伸之后的长度与拉伸之前长度的比值,按照公式(1)计算。
分别是薄膜拉伸之后和拉伸之前的长度。
本发明所制备的尼龙1111/聚偏氟乙烯复合铁电薄膜与纯聚偏氟乙烯相比剩余极化强度有很大的提高。其原理在于聚偏氟乙烯CF2偶极子和尼龙1111酰胺键偶极子之间有相互作用,发生了协同效应。
本发明使用的原料之一尼龙1111工业化成本低廉,复合薄膜的总体成本比聚偏氟乙烯更低。
本发明所述的一种尼龙1111/聚偏氟乙烯复合铁电薄膜制备方法简单,工业设备常见,容易操作,适合工业化生产。
附图说明
图1是对比例1纯尼龙1111的电滞回线曲线。
图2是对比例2聚偏氟乙烯的电滞回线曲线。
图3是实施例1的电滞回线曲线。
图4是实施例2的电滞回线曲线。
图5是实施例3的电滞回线曲线。
图6是实施例4的电滞回线曲线。
图7是实施例5的电滞回线曲线。
具体实施方式
为了进一步理解本发明,下面结合实例对本发明进行进一步描述,但本发明的保护范围不仅限于此。此外应理解,在阅读了本发明内容之后,有关技术人员可以对本发明做各种改动或者修改,如热压压力和热压时间,混炼机转速等,这些等价形式同样属于本发明技术方案所限定的范围。
实施例1
将尼龙1111和聚偏氟乙烯颗粒100°C真空干燥24小时,按照重量份将30份尼龙1111颗粒和70份聚偏氟乙烯加入Haake流变仪中共混,共混温度210°C,螺杆转速60r/min,共混时间5min。取共混料夹在两张铝箔之间,在热压机上热压成厚度50μm左右的薄膜。热压温度为210°C,热压压力6MPa,热压时间8min。再将处在熔融状态的薄膜迅速转移到冰水混合物中淬火,于20℃温度下,用质量浓度5%的氢氧化钠强碱溶液溶解淬火薄膜两面的铝箔,得到初始薄膜,自然干燥。室温下拉伸得到厚度30微米的拉伸薄膜样品,拉伸比n=3。
实施例2
将尼龙1111和聚偏氟乙烯颗粒80°C真空干燥24小时,按照按照重量份将50份尼龙1111颗粒和50份聚偏氟乙烯加入Haake流变仪中共混,共混温度210°C,螺杆转速60r/min,共混时间5min。取共混料夹在两张铝箔之间,热压机上热压成厚度50μm左右的薄膜。热压温度为210°C,热压压力6MPa,热压时间8min。再将处在熔融状态的薄膜迅速转移到冰水混合物中淬火,于10℃温度下,用质量浓度30%的氢氧化钾强碱溶液溶解淬火薄膜两面的铝箔,得到初始薄膜,自然干燥。室温下拉伸比n=3,拉伸得到厚度30微米的铁电复合薄膜样品。
实施例3
将尼龙1111和聚偏氟乙烯颗粒100°C真空干燥24小时,按照重量份将70份尼龙1111颗粒和30份聚偏氟乙烯加入Haake流变仪中共混,共混温度240°C,螺杆转速60r/min,共混时间5min。取共混料夹在两张铝箔之间,在热压机上热压成厚度50μm左右的薄膜。热压温度为220°C,热压压力6MPa,热压时间8min。再将处在熔融状态的薄膜迅速转移到冰水混合物中淬火,于0℃温度下,用质量浓度20%的氢氧化钠强碱溶液溶解淬火薄膜两面的铝箔,得到初始薄膜,自然干燥。50°C温度下在拉力机上拉伸,拉伸比n=3,拉伸得到厚度30微米的铁电复合薄膜样品。
实施例4
将尼龙1111和聚偏氟乙烯颗粒90°C真空干燥24小时,按照重量份将50份尼龙1111颗粒和50份聚偏氟乙烯加入Haake流变仪中共混,共混温度220°C,螺杆转速60r/min,共混时间5min。取共混料夹在两张铝箔之间,在热压机上热压成厚度50μm左右的薄膜。热压温度为230°C,热压压力6MPa,热压时间8min。再将处在熔融状态的薄膜迅速转移到冰盐水混合物中淬火,于10℃温度下,用质量浓度15%的氢氧化钾强碱溶液溶解淬火薄膜两面的铝箔,得到初始薄膜,自然干燥。80°C温度下在拉力机上拉伸,拉伸比n=4,拉伸得到厚度20微米的铁电复合薄膜样品。
实施例5
将尼龙1111和聚偏氟乙烯颗粒80°C真空干燥24小时,按照重量份将50份尼龙1111颗粒和50份聚偏氟乙烯加入Haake流变仪中共混,共混温度200°C,螺杆转速60r/min,共混时间5min。取共混料夹在两张铝箔之间,在热压机上热压成厚度50μm左右的薄膜。热压温度为230°C,热压压力6MPa,热压时间8min。室温下再将处在熔融状态的薄膜迅速转移到冰水混合物中淬火,于30℃温度下,用质量浓度10%的氢氧化钾强碱溶液溶解淬火薄膜两面的铝箔,得到初始薄膜,自然干燥。100°C温度下在拉力机上拉伸,拉伸比n=3,拉伸得到厚度30微米的铁电复合薄膜样品。
对比例1
将聚偏氟乙烯颗粒100°C真空干燥24小时后,加入Haake流变仪中共混,共混温度210°C,螺杆转速60r/min,共混时间5min。取共混料夹在两张铝箔之间,热压机上热压成厚度50μm左右的薄膜。热压温度为210°C,热压压力6MPa,热压时间8min。再将处在熔融状态的薄膜迅速转移到冰水混合物中淬火,于20℃温度下,用质量浓度5%的氢氧化钠强碱溶液溶解淬火薄膜两面的铝箔得到初始薄膜,自然干燥。室温下拉伸得到厚度30微米的拉伸薄膜样品,拉伸比n=3。
对比例2
将尼龙1111颗粒80°C真空真空干燥24小时后,加入Haake流变仪中共混,共混温度210°C,螺杆转速60r/min,共混时间5min。取共混料夹在两张铝箔之间,热压机上热压成厚度50μm左右的薄膜。热压温度为210°C,热压压力6MPa,热压时间8min。再将处在熔融状态的薄膜迅速转移到冰水混合物中淬火,于10℃温度下,用质量浓度30%的氢氧化钾强碱溶液溶解淬火薄膜两面的铝箔得到初始薄膜,自然干燥。室温下拉伸比n=3,拉伸得到厚度30微米的薄膜样品。
按以下方法测试样品薄膜的铁电性能,获得样品的剩余极化强度(P r )和矫顽电场(E c ),结果如表1所示。
在真空镀膜机中将样品薄膜两面蒸镀直径Φ=4.5mm的铝电极。铁电性能于室温下在德国aixACT公司产TF2000铁电测试***上完成测试。测试时将样品浸在硅油中,施加正弦电场,频率为1Hz。
表1 样品的剩余极化强度和矫顽电场
样品及编号 | 剩余极化强度 (mC/m2) | 矫顽电场 (MV/m) |
对比例1:PA1111 | 39 | 85 |
对比例2:PVDF | 38 | 55 |
实施例1:30/70 | 42 | 73 |
实施例2:50/50 | 53 | 88 |
实施例3:70/30 | 48 | 76 |
实施例4:50/50-n | 52 | 83 |
实施例5: 50/50-T | 55 | 89 |
图1和图2分别是奇-奇尼龙1111和聚偏氟乙烯的电滞回线,表明它们都具有铁电性。由表1可知,纯尼龙1111与聚偏氟乙烯的剩余极化强度相当,分别为39 mC/m2和38 mC/m2。尼龙1111矫顽电场值85MV/m高于聚偏氟乙烯的55MV/m。
图3-7分别是实施例1-5不同条件制备的复合薄膜的电滞回线曲线。电滞回线表明复合薄膜都具有铁电性。样品的剩余极化强度和矫顽电场值列于表1中。从表1中可知,复合薄膜的剩余极化强度比纯尼龙1111和聚偏氟乙烯薄膜的剩余极化强度要大,复合后的P r 都得到提高;复合后薄膜的矫顽电场有所增加。实施例2、实施例4和实施例5剩余极化强度均在50 mC/m2以上,远高于同样条件下聚偏氟乙烯薄膜的剩余极化强度。这说明尼龙1111和聚偏氟乙烯复合后产生了协同效应。
尼龙1111和聚偏氟乙烯的配比会影响铁电性。尼龙1111和聚偏氟乙烯配比为50/50效果较好。
拉伸比能影响铁电性能。拉伸比增大,铁电微区更容易取向,矫顽电场降低。但剩余极化强度变化不大。
较高温度下拉伸,结晶度增大,剩余极化强度增加;但是铁电微区取向变得困难,矫顽电场增大。
Claims (4)
1.一种尼龙1111/聚偏氟乙烯铁电复合薄膜,其特征在于,通过以下方法制备而成:
(1)称量原料尼龙1111与聚偏氟乙烯,尼龙1111重量份为50,聚偏氟乙烯重量份为50,于80~100℃真空干燥;
(2)将干燥后的原料混合,在熔融混炼设备上共混,温度200~240℃,得到尼龙1111/聚偏氟乙烯共混物;
(3)将尼龙1111/聚偏氟乙烯共混物用铝箔包裹在热压设备上热压成厚度为30~50微米薄膜,热压温度210~230℃;
(4)将处在熔融状态的薄膜迅速在冰水混合物或冰盐水中淬火,得到淬火薄膜;
(5)强碱溶液溶解淬火薄膜两面的铝箔得到初始薄膜,自然干燥;
(6)将初始薄膜在拉力机上拉伸,拉伸温度20~100℃,拉伸比n为0.5~5,得到厚度10~30微米的铁电复合薄膜。
2.如权利要求1所述的一种尼龙1111/聚偏氟乙烯铁电复合薄膜,其特征在于,步骤(5)所述的强碱溶液为氢氧化钠溶液或氢氧化钾溶液,溶液质量浓度范围5%~30%。
3.制备权利要求1所述的尼龙1111/聚偏氟乙烯铁电复合薄膜的方法,其特征在于,通过以下方法实现:
(1)称量原料尼龙1111与聚偏氟乙烯,尼龙1111重量份为50,聚偏氟乙烯重量份为50,于80~100℃真空干燥;
(2)将干燥后的原料混合,在熔融混炼设备上共混,温度200~240℃,得到尼龙1111/聚偏氟乙烯共混物;
(3)将尼龙1111/聚偏氟乙烯共混物用铝箔包裹在热压设备上热压成厚度为30~50微米薄膜,热压温度210~230℃;
(4)将处在熔融状态的薄膜迅速在冰水混合物或冰盐水中淬火,得到淬火薄膜;
(5)强碱溶液溶解淬火薄膜两面的铝箔得到初始薄膜,自然干燥;
(6)将初始薄膜在拉力机上拉伸,拉伸温度20~100℃,拉伸比n为0.5~5,得到厚度10~30微米的铁电复合薄膜。
4.如权利要求3所述的方法,其特征在于,步骤(5) 所述的强碱溶液为氢氧化钠溶液或氢氧化钾溶液,溶液质量浓度范围5%~30%。
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