CN106673634B - 一种量子磁片材料 - Google Patents
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Abstract
本发明涉及新材料技术领域,具体涉及一种量子磁片材料,包括以下原料以重量份计:火山岩石、电气石、锗石、稀土、石墨烯微片、矾石、镁、独居石、氧化铝。本发明的量子磁片材料的原料组分简单易得,制备成本低,利用无机矿石,使制得的量子磁片材料具有温热效应、改善新陈代谢、提高机体免疫的功能,同时加入石墨烯微片,利用石墨烯优异的导热性能和吸附性能,能够提高磁片材料的温热效应,吸附污染物,应用于鞋垫中,对促进人体身体健康、增强血液循环、调整人体微循环、改善新陈代谢、提高机体免疫具有重要意义。
Description
技术领域
本发明涉及新材料技术领域,具体涉及一种量子磁片材料。
背景技术
电气石是以含硼为特征的铝、铁、钠、镁、锂的环状结构硅酸盐矿物,呈黑色或灰黑色,粗针状、束状或放射状结构。电气石具有特殊的热电性和压电性,有很高的远红外辐射和负离子释放能力,并含有多种对人体健康有益的微量元素,广泛应用在饮用水活性化、空气净化、污水处理、陶瓷、建材、日用化工、电子、纺织、保健用品、美容化妆品等领域。火山岩石又称喷出岩(Effusive rock),属于岩浆岩(火成岩)的一类,是火山作用时喷出的岩浆经冷凝、成岩、压实等作用形成的岩石,含有大量的硅、钾、钠、铁、镁、26种矿物元素,以及铜、锌、铬、镍、锰等,加热后的火山岩会释放出大量雾状的能量离子同时产生磁效应、温热效应、冷热效应。石墨烯是一种由碳原子构成的单层片状结构的新材料,是目前世上最薄却最坚硬的纳米材料,具有独特的物理化学性质。石墨烯与有机污染物之间可形成非常强的络合能力,从而对有机污染物有很强的吸附能力。此外,石墨烯具有良好的导热性[3000W/(m·K) ]、高强度(110GPa) 和超大的比表面积(2630m/g)。这些优异的性能使得石墨烯在纳米电子器件、气体传感器、能量存储及复合材料等领域有光明的应用前景。然而石墨烯的制备工艺复杂,越薄的石墨烯制备成本越高,因此,受成本限制,石墨烯的应用很难取得大的突破。
而另一方面,随着社会的发展和人们生活水平的提高,越来越注重环保与健康,特别是在日用品方面,普通的日用陶瓷已经不能满足人们对保健性能的要求,因此,本发明提供一种制备方法简单、制备成本低的量子磁片材料,以弥补现有技术中的不足。
发明内容
本发明的目的在于克服现有技术的不足,提供一种量子磁片材料,原料组分简单易得,制备成本低,具有磁效应、温热效应、改善新陈代谢、提高机体免疫的功能。
本发明的目的是通过以下技术方案来实现的:
一种量子磁片材料,包括以下原料以重量份计:火山岩石14~18重量份,电气石10~12重量份,锗石3~5重量份,稀土14~18重量份,石墨烯微片6~10重量份,矾石4~6重量份,镁4~6重量份,独居石6~10重量份,氧化铝10~14重量份。
进一步地,包括以下原料以重量份计:火山岩石16重量份,电气石11重量份,锗石5重量份,稀土15重量份,石墨烯微片8重量份,矾石4重量份,镁6重量份,独居石9重量份,氧化铝12重量份。
进一步地,所述火山岩石、电气石、锗石、稀土、矾石、独居石的粒径分别为0.8~5μm。
进一步地,所述镁为粒径1~4μm的颗粒。
进一步地,所述氧化镁为粒径5~10μm的颗粒。
进一步地,所述石墨烯微片的粒径为1~10微米,径厚比为5~20:1。
上述量子磁片材料的制备方法,包括以下步骤:依次将火山岩石、电气石、锗石、稀土、石墨烯微片、矾石、镁、独居石、氧化铝搅拌混合均匀,得到混合料;然后将混合料放入模具,在蒸汽环境中,在1560~1600℃下做压模处理45~60min,然后温度降至1200~1250℃,稳温50~60min,再降温至800~850℃,稳温40~45min,然后自然冷却成型,得到量子磁片材料。
一种鞋垫,包上述量子磁片材料。
本发明的有益效果是:本发明的量子磁片材料的原料组分简单易得,制备成本低,利用火山岩石、电气石、锗石、稀土、麦饭石、矾石、独居石等无机矿石,使制得的量子磁片材料具有温热效应、抗菌通络、改善新陈代谢、提高机体免疫的功能,同时加入一定粒径的石墨烯微片,利用石墨烯优异的导热性能和吸附性能,能够提高磁片材料的温热效应,同时吸附污染物,应用于鞋垫中,对促进人体身体健康、增强血液循环、调整人体微循环、改善新陈代谢、提高机体免疫具有重要意义。
具体实施方式
下面结合具体实施例进一步详细描述本发明的技术方案,但本发明的保护范围不局限于以下所述。
实施例1
一种量子磁片材料,包括以下原料以重量份计:火山岩石14重量份,电气石10重量份,锗石5重量份,稀土14重量份,石墨烯微片6重量份,矾石6重量份,镁5重量份,独居石10重量份,氧化铝10重量份;所述镁为粒径1~4μm的颗粒;所述氧化镁为粒径5~10μm的颗粒;所述石墨烯微片的粒径为1~10微米,径厚比为5~20:1;
依次将火山岩石、电气石、锗石、稀土、石墨烯微片、矾石、镁、独居石、氧化铝搅拌混合均匀,得到混合料;然后将混合料放入模具,在蒸汽环境中,在1560~1600℃下做压模处理45~60min,然后温度降至1200~1250℃,稳温50~60min,再降温至800~850℃,稳温40~45min,然后自然冷却成型,得到量子磁片材料。
实施例2
一种量子磁片材料,包括以下原料以重量份计:火山岩石18重量份,电气石12重量份,锗石4重量份,稀土16重量份,石墨烯微片10重量份,矾石4重量份,镁4重量份,独居石6重量份,氧化铝13重量份;所述镁为粒径1~4μm的颗粒;所述氧化镁为粒径5~10μm的颗粒;所述石墨烯微片的粒径为1~10微米,径厚比为5~20:1;
依次将火山岩石、电气石、锗石、稀土、石墨烯微片、矾石、镁、独居石、氧化铝搅拌混合均匀,得到混合料;然后将混合料放入模具,在蒸汽环境中,在1560~1600℃下做压模处理45~60min,然后温度降至1200~1250℃,稳温50~60min,再降温至800~850℃,稳温40~45min,然后自然冷却成型,得到量子磁片材料。
实施例3
一种量子磁片材料,包括以下原料以重量份计:火山岩石15重量份,电气石10重量份,锗石3重量份,稀土18重量份,石墨烯微片7重量份,矾石4.5重量份,镁6重量份,独居石8重量份,氧化铝14重量份;所述镁为粒径1~4μm的颗粒;所述氧化镁为粒径5~10μm的颗粒;所述石墨烯微片的粒径为1~10微米,径厚比为5~20:1;
依次将火山岩石、电气石、锗石、稀土、石墨烯微片、矾石、镁、独居石、氧化铝搅拌混合均匀,得到混合料;然后将混合料放入模具,在蒸汽环境中,在1560~1600℃下做压模处理45~60min,然后温度降至1200~1250℃,稳温50~60min,再降温至800~850℃,稳温40~45min,然后自然冷却成型,得到量子磁片材料。
实施例4
一种量子磁片材料,包括以下原料以重量份计:火山岩石16重量份,电气石11重量份,锗石5重量份,稀土15重量份,石墨烯微片8重量份,矾石4重量份,镁6重量份,独居石9重量份,氧化铝12重量份;所述镁为粒径1~4μm的颗粒;所述氧化镁为粒径5~10μm的颗粒;所述石墨烯微片的粒径为1~10微米,径厚比为5~20:1;
依次将火山岩石、电气石、锗石、稀土、石墨烯微片、矾石、镁、独居石、氧化铝搅拌混合均匀,得到混合料;然后将混合料放入模具,在蒸汽环境中,在1560~1600℃下做压模处理45~60min,然后温度降至1200~1250℃,稳温50~60min,再降温至800~850℃,稳温40~45min,然后自然冷却成型,得到量子磁片材料。
以上所述仅是本发明的优选实施方式,应当理解本发明并非局限于本文所披露的形式,不应看作是对其他实施例的排除,而可用于各种其他组合、修改和环境,并能够在本文所述构想范围内,通过上述教导或相关领域的技术或知识进行改动。而本领域人员所进行的改动和变化不脱离本发明的精神和范围,则都应在本发明所附权利要求的保护范围内。
Claims (7)
1.一种鞋垫用量子磁片材料,其特征在于,包括以下原料以重量份计:火山岩石14~18重量份,电气石10~12重量份,锗石3~5重量份,稀土14~18重量份,石墨烯微片6~10重量份,矾石4~6重量份,镁4~6重量份,独居石6~10重量份,氧化铝10~14重量份;
其制备方法为:依次将火山岩石、电气石、锗石、稀土、石墨烯微片、矾石、镁、独居石、氧化铝搅拌混合均匀,得到混合料;然后将混合料放入模具,在蒸汽环境中,在1560~1600℃下做压模处理45~60min,然后温度降至1200~1250℃,稳温50~60min,再降温至800~850℃,稳温40~45min,然后自然冷却成型,得到量子磁片材料。
2.根据权利要求1所述的一种鞋垫用量子磁片材料,其特征在于,包括以下原料以重量份计:火山岩石16重量份,电气石11重量份,锗石5重量份,稀土15重量份,石墨烯微片8重量份,矾石4重量份,镁6重量份,独居石9重量份,氧化铝12重量份。
3.根据权利要求1所述的一种鞋垫用量子磁片材料,其特征在于,所述火山岩石、电气石、锗石、稀土、矾石、独居石的粒径分别为0.8~5μm。
4.根据权利要求1所述的一种鞋垫用量子磁片材料,其特征在于,所述镁为粒径1~4μm的颗粒。
5.根据权利要求1所述的一种鞋垫用量子磁片材料,其特征在于,所述石墨烯微片的粒径为1~10微米,径厚比为5~20:1。
6.一种如权利要求1-5任意一项所述鞋垫用量子磁片材料的制备方法,其特征在于,包括以下步骤:依次将火山岩石、电气石、锗石、稀土、石墨烯微片、矾石、镁、独居石、氧化铝搅拌混合均匀,得到混合料;然后将混合料放入模具,在蒸汽环境中,在1560~1600℃下做压模处理45~60min,然后温度降至1200~1250℃,稳温50~60min,再降温至800~850℃,稳温40~45min,然后自然冷却成型,得到量子磁片材料。
7.一种鞋垫,其特征在于,包含权利要求1-5任意一项所述鞋垫用量子磁片材料。
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