CN109592976A - 一种高强度防伪瓶口及其加工方法 - Google Patents

一种高强度防伪瓶口及其加工方法 Download PDF

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CN109592976A
CN109592976A CN201811397381.6A CN201811397381A CN109592976A CN 109592976 A CN109592976 A CN 109592976A CN 201811397381 A CN201811397381 A CN 201811397381A CN 109592976 A CN109592976 A CN 109592976A
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谈作乾
马协初
王剑鹏
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YIXING GOLDFISH CERAMICS CO Ltd
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Abstract

本发明提供了一种高强度防伪瓶口及其加工方法,其特征在于,所述瓶口配料及配料组份占比如下:Al2O3:17‑18,SiO2:70‑71,K2O:2.5‑3,Na2O:1‑1.5,CaO:1‑1.5,MgO:1‑1.5。本发明方法制作的陶瓷防伪瓶口膨胀均匀,热震稳定性好,硬度大,大大增加了防伪陶瓷瓶口的强度,减少了压盖过程中的破损,保证了瓶口的密封性和稳定性,对高端白酒的品质提供更加有力的保障。

Description

一种高强度防伪瓶口及其加工方法
技术领域
本发明主要涉及瓶口加工的技术领域,具体涉及一种高强度防伪瓶口及其加工方法。
背景技术
目前市场上已经有很多酒厂使用陶瓷酒瓶作为酒体的包装容器,尤其是一些高端白酒对陶瓷酒瓶更是推崇,因此对陶瓷酒瓶防伪瓶口的防伪功能,安全性,稳定性上要求越来越高。普通陶瓷具有一定的脆性,防伪陶瓷瓶口在与防伪瓶盖的配合过程中,会受到很大的摩擦力和冲击力(尤其是不锈钢材质的瓶盖),瓶口棱角部位在压盖过程中有可能产生陶瓷碎屑,造成食品安全隐患。
发明内容
本发明主要提供了一种高强度防伪瓶口及其加工方法,用以解决上述背景技术中提出的技术问题。
本发明解决上述技术问题采用的技术方案为:一种高强度防伪瓶口及其加工方法,所述瓶口配料及配料组份占比如下:Al2O3:17-18,SiO2:70-71,K2O:2.5-3,Na2O:1-1.5,CaO:1-1.5,MgO:1-1.5。
优选的,所述瓶口配料及配料组份占比如下:Al2O3:17-18,SiO2:70-71,K2O:2.5-3,Na2O:1-1.5,CaO:1-1.5,MgO:1-1.5和余量莫来石。
优选的,所述防伪陶瓷瓶口的加工方法如下:原料配比球磨→过筛除铁→压滤→陈腐→真空练泥→液压成型→旋转切削→装箱保湿待用→烧制成型。
优选的,所有原料经过球磨后,必须通过10X10um的目筛,直至所有原料研磨后的原料符合筛选要求即止。
优选的,在最后烧制成型时,其温度控制在1150℃~1250℃之间。
优选的,所述防伪瓶口各成分占比如下:Al2O3:17,SiO2:70,K2O:2.5,Na2O:1,CaO:1,MgO:1。
优选的,所述防伪瓶口各成分占比如下:Al2O3:18,SiO2:71,K2O:3,Na2O:1.5,CaO:1.5,MgO:1.5。
优选的,所述瓶口配料及配料组份占比如下:Al2O3:17,SiO2:70,K2O:2.5,Na2O:1,CaO:1,MgO:1和余量莫来石。
优选的,所述瓶口配料及配料组份占比如下:Al2O3:18,SiO2:71,K2O:3,Na2O:1.5,CaO:1.5,MgO:1.5和余量莫来石。
与现有技术相比,本发明的有益效果为:本发明方法制作的陶瓷防伪瓶口膨胀均匀,热震稳定性好,硬度大,大大增加了防伪陶瓷瓶口的强度,减少了压盖过程中的破损,保证了瓶口的密封性和稳定性,对高端白酒的品质提供更加有力的保障。
以下将结合具体的实施例对本发明进行详细的解释说明。
具体实施方式
现详细说明本发明的多种示例性实施方式,该详细说明不应认为是对本发明的限制,而应理解为是对本发明的某些方面、特性和实施方案的更详细的描述。
在不背离本发明的范围或精神的情况下,可对本发明说明书的具体实施方式做多种改进和变化,这对本领域技术人员而言是显而易见的。由本发明的说明书得到的其他实施方式对技术人员而言是显而易见得的。本申请说明书和实施例仅是示例性的。
实施例1
S001:预先称取17质量份的Al2O3、70质量份的SiO2、2.5质量份的K2O、1质量份的Na2O、1质量份的CaO和1质量份的MgO;
S002:再讲称取后的原料加入到球磨机内,利用球磨机对原料进行研磨,再将研磨后的原料逐一通过10X10的目筛,未通过筛选的原料继续加入到球磨机内,直到所有原料全部通过目筛后即止;
S003:将研磨后的原料加入浮选机内,通过浮选机的作用,将原料粉末内的铁杂质去除,再通过浮选机将混入的其它杂质过滤;
S004:将混合后的原料放入到地窖内,存储10-15天取出;
S005:将取出原料加入到真空练泥机内,使得组份之间混合更加均匀,混合加工超过30-45分钟后即止,再将真空练泥机内的原料取出,加入到液压机内,通过液压机,将原料加工成所需要的瓶口胚型;
S006:通过旋切机,对瓶口胚体进行旋切加工,精加工成型;
S007:将精加工成型后的瓶口胚体保湿,进行封箱保存;
S008:将封箱后的瓶口胚体装接在瓶坯口部,进入辊道窑高温烧成一体即可。
实施例2
S001:预先称取18质量份的Al2O3、71质量份的SiO2、3质量份的K2O、1.5质量份的Na2O、1.5质量份的CaO和1.5质量份的MgO;
S002:再讲称取后的原料加入到球磨机内,利用球磨机对原料进行研磨,再将研磨后的原料逐一通过10X10的目筛,未通过筛选的原料继续加入到球磨机内,直到所有原料全部通过目筛后即止;
S003:将研磨后的原料加入浮选机内,通过浮选机的作用,将原料粉末内的铁杂质去除,再通过浮选机将混入的其它杂质过滤;
S004:将混合后的原料放入到地窖内,存储10-15天取出;
S005:将取出原料加入到真空练泥机内,使得组份之间混合更加均匀,混合加工超过30-45分钟后即止,再将真空练泥机内的原料取出,加入到液压机内,通过液压机,将原料加工成所需要的瓶口胚型;
S006:通过旋切机,对瓶口胚体进行旋切加工,精加工成型;
S007:将精加工成型后的瓶口胚体保湿,进行封箱保存;
S008:将封箱后的瓶口胚体装接在瓶坯口部,进入辊道窑高温烧成一体即可。
实施例3
S001:预先称取17质量份的Al2O3、70质量份的SiO2、2.5质量份的K2O、1质量份的Na2O、1质量份的CaO和1质量份的MgO和余量的莫来石;
S002:再讲称取后的原料加入到球磨机内,利用球磨机对原料进行研磨,再将研磨后的原料逐一通过10X10的目筛,未通过筛选的原料继续加入到球磨机内,直到所有原料全部通过目筛后即止;
S003:将研磨后的原料加入浮选机内,通过浮选机的作用,将原料粉末内的铁杂质去除,再通过浮选机将混入的其它杂质过滤;
S004:将混合后的原料放入到地窖内,存储10-15天取出;
S005:将取出原料加入到真空练泥机内,使得组份之间混合更加均匀,混合加工超过30-45分钟后即止,再将真空练泥机内的原料取出,加入到液压机内,通过液压机,将原料加工成所需要的瓶口胚型;
S006:通过旋切机,对瓶口胚体进行旋切加工,精加工成型;
S007:将精加工成型后的瓶口胚体保湿,进行封箱保存;
S008:将封箱后的瓶口胚体装接在瓶坯口部,进入辊道窑高温烧成一体即可。
实施例4
S001:预先称取18质量份的Al2O3、71质量份的SiO2、3质量份的K2O、1.5质量份的Na2O、1.5质量份的CaO和1.5质量份的MgO和余量的莫来石;
S002:再讲称取后的原料加入到球磨机内,利用球磨机对原料进行研磨,再将研磨后的原料逐一通过10X10的目筛,未通过筛选的原料继续加入到球磨机内,直到所有原料全部通过目筛后即止;
S003:将研磨后的原料加入浮选机内,通过浮选机的作用,将原料粉末内的铁杂质去除,再通过浮选机将混入的其它杂质过滤;
S004:将混合后的原料放入到地窖内,存储10-15天取出;
S005:将取出原料加入到真空练泥机内,使得组份之间混合更加均匀,混合加工超过30-45分钟后即止,再将真空练泥机内的原料取出,加入到液压机内,通过液压机,将原料加工成所需要的瓶口胚型;
S006:通过旋切机,对瓶口胚体进行旋切加工,精加工成型;
S007:将精加工成型后的瓶口胚体保湿,进行封箱保存;
S008:将封箱后的瓶口胚体装接在瓶坯口部,进入辊道窑高温烧成一体即可。
以上所述仅为本发明示意性的具体实施方式,在不脱离本发明的构思和原则的前提下,任何本领域的技术人员所做出的等同变化与修改,均应属于本发明保护的范围。

Claims (9)

1.一种高强度防伪瓶口及其加工方法,其特征在于,所述瓶口配料及配料组份占比如下:Al2O3:17-18,SiO2:70-71,K2O:2.5-3,Na2O:1-1.5,CaO:1-1.5,MgO:1-1.5。
2.一种高强度防伪瓶口及其加工方法,其特征在于,所述瓶口配料及配料组份占比如下:Al2O3:17-18,SiO2:70-71,K2O:2.5-3,Na2O:1-1.5,CaO:1-1.5,MgO:1-1.5和余量莫来石。
3.根据权利要求1所述的一种高强度防伪瓶口及其加工方法,其特征在于,所述防伪陶瓷瓶口的加工方法如下:原料配比球磨→过筛除铁→压滤→陈腐→真空练泥→液压成型→旋转切削→装箱保湿待用→烧制成型。
4.根据权利要求3所述的一种高强度防伪瓶口及其加工方法,其特征在于,所有原料经过球磨后,必须通过10X10um的目筛,直至所有原料研磨后的原料符合筛选要求即止。
5.根据权利要求3所述的一种高强度防伪瓶口及其加工方法,其特征在于,在最后烧制成型时,其温度控制在1150℃~1250℃之间。
6.根据权利要求1所述的一种高强度防伪瓶口及其加工方法,其特征在于,所述防伪瓶口各成分占比如下:Al2O3:17,SiO2:70,K2O:2.5,Na2O:1,CaO:1,MgO:1。
7.根据权利要求1所述的一种高强度防伪瓶口及其加工方法,其特征在于,所述防伪瓶口各成分占比如下:Al2O3:18,SiO2:71,K2O:3,Na2O:1.5,CaO:1.5,MgO:1.5。
8.根据权利要求1所述的一种高强度防伪瓶口及其加工方法,其特征在于,所述瓶口配料及配料组份占比如下:Al2O3:17,SiO2:70,K2O:2.5,Na2O:1,CaO:1,MgO:1和余量莫来石。
9.根据权利要求1所述的一种高强度防伪瓶口及其加工方法,其特征在于,所述瓶口配料及配料组份占比如下:Al2O3:18,SiO2:71,K2O:3,Na2O:1.5,CaO:1.5,MgO:1.5和余量莫来石。
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