标准解读
GB/Z 44235-2024是一项中国国家标准指导性技术文件,专注于纳米技术领域中含聚合物纳米纤维的空气过滤介质的特性及其测量方法。此标准为理解、评估和对比此类材料提供了统一的框架和指导原则。
标准范围
该标准详细阐述了含有聚合物纳米纤维的空气过滤介质的关键性能特征,这些特征直接关联到其在空气净化、污染控制以及其他需要高效过滤的应用中的效能。聚合物纳米纤维因其独特的微观结构和高比表面积,在提高过滤效率、降低空气阻力以及增强对微小颗粒物捕获能力方面展现出显著优势。
特性描述
标准内具体描述的特性可能包括但不限于:
- 过滤效率:衡量过滤介质去除空气中特定大小颗粒物的能力。
- 压力损失(或称为空气阻力):表示空气通过过滤介质时压降的大小,影响能耗和系统设计。
- 容尘量:过滤介质在达到设计使用极限前所能容纳的灰尘量,直接影响使用寿命。
- 透气性:描述空气通过过滤介质的难易程度,与过滤效率和压力损失紧密相关。
- 微生物阻隔性能:对于特定应用,如医疗卫生领域,此特性尤为重要。
测量方法
标准还规定了上述特性的标准化测量方法,确保不同实验室间测试结果的可比性和重复性。这包括:
- 过滤效率测试:通常采用颗粒计数法或质量法,依据特定的标准粒径分布挑战,评估过滤效果。
- 压差测量:在恒定流量下测定过滤前后空气压力的变化,以计算压力损失。
- 容尘试验:通过模拟实际工作条件,测量过滤介质达到预定阻力或效率下降至某一水平前的累计尘埃负载。
- 透气性测试:在标准条件下测量单位面积过滤介质允许空气通过的体积流量。
应用指导
虽然未直接要求总结,但可以理解,该标准旨在为制造商、检测机构及用户等提供一个共同遵循的基准,确保含聚合物纳米纤维空气过滤介质的质量控制、性能评价及产品开发有据可依,促进技术进步和市场规范化。它不仅有助于提升空气净化产品的性能和可靠性,也对环境保护、公共卫生安全以及相关行业标准的国际化对接具有重要意义。
如需获取更多详尽信息,请直接参考下方经官方授权发布的权威标准文档。
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- 2024-08-23 颁布
- 2025-03-01 实施
文档简介
ICS07.120
CCSL04
中华人民共和国国家标准化指导性技术文件
GB/Z44235—2024/ISO/TS21237:2020
纳米技术含聚合物纳米纤维的
空气过滤介质特性及测量方法
Nanotechnologies—Characteristicsandmeasurementmethodsofair
filtermediacontainingpolymericnanofibers
(ISO/TS21237:2020,Nanotechnologies—Airfiltermediacontainingpolymeric
nanofibers—Specificationofcharacteristicsandmeasurementmethods,IDT)
2024⁃08⁃23发布2025⁃03⁃01实施
国家市场监督管理总局
国家标准化管理委员会发布
GB/Z44235—2024/ISO/TS21237:2020
目次
前言··························································································································Ⅲ
引言··························································································································Ⅳ
1范围·······················································································································1
2规范性引用文件········································································································1
3术语和定义··············································································································1
4缩略语····················································································································2
5待测特性及其测量方法·······························································································2
5.1概述·················································································································2
5.2基本特性和可选特性及其测量方法··········································································2
5.3特性及其测量方法的描述······················································································3
5.3.1概述············································································································3
5.3.2纤维直径······································································································3
5.3.3形貌············································································································3
5.3.4比表面积······································································································4
5.3.5化学组成······································································································4
5.3.6热稳定性······································································································4
5.3.7晶体结构······································································································4
5.3.8结晶度·········································································································5
5.3.9晶粒尺寸······································································································5
6报告·······················································································································5
附录A(资料性)含纳米纤维空气过滤介质的典型结构························································6
附录B(资料性)基本特性的检测报告格式········································································8
附录C(资料性)可选特性的检测报告格式········································································9
参考文献····················································································································10
Ⅰ
GB/Z44235—2024/ISO/TS21237:2020
前言
本文件按照GB/T1.1—2020《标准化工作导则第1部分:标准化文件的结构和起草规则》的规
定起草。
本文件等同采用ISO/TS21237—2020《纳米技术含聚合物纳米纤维的空气过滤介质特性及
测量方法规范》,文件类型由ISO的技术规范调整为我国的国家标准化指导性技术文件。
本文件做了下列最小限度的编辑性改动:
——为与现有标准协调,将标准名称更改为《纳米技术含聚合物纳米纤维的空气过滤介质特性
及测量方法》。
请注意本文件的某些内容可能涉及专利。本文件的发布机构不承担识别专利的责任。
本文件由中国科学院提出。
本文件由全国纳米技术标准化技术委员会(SAC/TC279)归口。
本文件起草单位:中国医学科学院基础医学研究所、嘉兴富瑞邦新材料科技有限公司、中国科学院
苏州纳米技术与纳米仿生研究所。
本文件主要起草人:刘健、温涛、许海燕、赵兴雷、蒋攀、华婷、张学同、盛智芝。
Ⅲ
GB/Z44235—2024/ISO/TS21237:2020
引言
空气过滤介质对不同类型空气过滤器的性能和效率有重要作用。大多数空气过滤介质利用无纺
材料分离固体或液体微粒。空气过滤介质应用广泛,如用于燃气轮机进气、工业除尘、呼吸面罩、个人
防护设备、供暖、通风和空调系统、洁净室等。
近年来,含纳米纤维的空气过滤介质由于其具有高过滤效率和滑流效应所带来的低压降特性(见
参考文献[5]),已商业化并被广泛应用于不同行业。含纳米纤维的空气过滤介质通常可通过在纺丝过
程中将一种或多种聚合物基纳米纤维直接沉积在适当的多孔基底表面而获得。
由于纳米纤维的直径显著小于过滤器中使用的传统微纤维,因此能够提高惯性碰撞和拦截的几
率,从而获得更高的过滤效率。同时,滑流也能够减小压降,使更多的污染物流经纳米纤维表面,因而
也能提高惯性碰撞和拦截效率。在压降相同的情况下,纳米纤维层的过滤能力优于传统纤维层。此
外,纳米纤维的高比表面积有助于从空气中吸附污染物。以上这些优点使含纳米纤维的空气过滤介质
广泛用于空气过滤(见参考文献[5][6][7])。
含纳米纤维的空气过滤介质可通过静电纺丝、离心纺丝等不同的技术进行制造。纳米纤维具有不
同的晶体结构、形貌和直径,其沉积在基底表面形成网状无纺层。无纺层的比表面积和互穿纤维的孔
隙率主要受纳米纤维直径和形貌的影响。聚酰胺(PA)、聚偏氟乙烯(PVDF)、聚丙烯腈(PAN)和聚氨
酯(PU)等材质的高分子纳米纤维通常被用于空气过滤介质。纳米纤维可以沉积在不同种类的纺织或
无纺基底上。附录A显示了含纳米纤维空气过滤介质的截面示意图(见图A.1)及显示其典型结构、形
貌和纹理的SEM图像(见图A.2和图A.3)。
本文件有助于促进供需双方的沟通,并为该类新型空气过滤介质不断增长的贸易提供支持。
Ⅳ
GB/Z44235—2024/ISO/TS21237:2020
纳米技术含聚合物纳米纤维的
空气过滤介质特性及测量方法
1范围
本文件规定了基底表面含聚合物纳米纤维的空气过滤介质宜测量的特性,并描述了相应的测量
方法。
本文件不涉及健康和安全相关的特性。
注:使用已公布的相关标准对空气过滤介质与应用相关的性质/性能进行评估。采用适合于特定应用的测试方法
对过滤介质的压降和颗粒去除效率等物理性质和性能进行测量。
2规范性引用文件
本文件没有规范性引用文件。
3术语和定义
下列术语和定义适用于本文件。
3.1
空气过滤器airfilter
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