气体中微米级颗粒的数量浓度溯源技术研究

doi:10.3969/j.issn.1000-1158.2023.11.18

摘要
图/表
参考文献(21)
相关文章 (15)

全文: PDF (4073 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要为建立气体中微米级颗粒数量浓度的量值溯源链,开展了基于喷墨原理气溶胶发生器(NIM-IJAG)的研制和性能验证。喷墨气溶胶发生器(NIM-IJAG)所发生的固体颗粒粒径及浓度值与喷嘴孔径、溶质密度、溶液浓度、电控参数、洁净空气流量等参数密切相关,其中在准确获得液滴粒径的前提下,通过改变溶液浓度,可实现对固体颗粒样品粒径的有效控制,通过调节发生频率可实现对固体颗粒样品数量浓度的有效控制。经实验验证,NIM-IJAG可产生粒径值在1~20μm范围、颗粒数量浓度在0~30个/cm³范围的单分散固体颗粒样品,颗粒数量浓度的量值可溯源至国家计量标准。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	郭黎旭
	刘俊杰
	刘悦
	叶婧
	任军

关键词 ：计量学, 气溶胶颗粒, 颗粒数量浓度, 溯源技术, 喷墨气溶胶发生器

Abstract：To study the traceability technology of the number concentration of airborne particles in micrometer range, an inkjet aerosol generator (NIM-IJAG) is developed and its performance is verified. The particle size and number concentration of obtained solid particles by NIM-IJAG are closely related to the nozzle aperture, solute density, solution mass concentration, output parameters of electrical controller, clean air flow volume and other parameters. On the basis of accurately obtaining the droplet size, the effective control of the particle size of solid particles can be achieved by changing the solution concentration, the number concentration of solid particles could be effectively controlled by adjusting the voltage frequency applied on the nozzle. Through experimental verification, NIM-IJAG can produce 1~20μm monodisperse solid particle samples with number concentration in 0~30/cm³, which can trace to the national metrology standard.

Key words： metrology airborne particle number concentration of particles traceability technology ink-jet aerosol generator

收稿日期: 2023-03-06 发布日期: 2023-11-17

PACS:

TH99

基金资助:中国计量科学研究院能力提升专项(ANL2203);中国计量科学研究院基本科研业务费(AKYZD2207-4,AKY1809)

通讯作者: 刘俊杰(1975-),山西平遥人,中国计量科学研究院,主要从事颗粒计量和气溶胶测量技术方面的研究。Email:liujj@nim.ac.cn E-mail: liujj@nim.ac.cn

作者简介: 郭黎旭(1996-),四川眉山人,太原理工大学硕士研究生,研究方向为颗粒计量和生物气溶胶。Email:Lixu_GUO@163.com

引用本文:

郭黎旭,刘俊杰,刘悦,叶婧,任军. 气体中微米级颗粒的数量浓度溯源技术研究[J]. 计量学报, 2023, 44(11): 1755-1762.
GUO Li-xu,LIU Jun-jie,LIU Yue,YE Jing,REN Jun. Traceability Research of Airborne Particle Number Concentration in Micrometer-scale. Acta Metrologica Sinica, 2023, 44(11): 1755-1762.

链接本文:

http://jlxb.china-csm.org:81/Jwk_jlxb/CN/10.3969/j.issn.1000-1158.2023.11.18 或 http://jlxb.china-csm.org:81/Jwk_jlxb/CN/Y2023/V44/I11/1755

	Liu L, Zhang W J, Du S Y, et al. Seasonal variation characteristics and potential source contribution of sulfate, nitrate and ammonium in Beijing by using single particle aerosol mass spectrometry ［J］. Environmental Science, 2016, 37(5): 1609-1618.
	Zhang L B, Yin L F, Li M J, et al. Study on particle size change of particulates during spring festival in Tianjin by single particle aerosol mass spectrometry ［J］. Tianjin Science & Technology, 2020, 47(4): 67-72.
［4］	师耀龙, 王瑜, 魏连涛, 等. PM1与PM2. 5切割器性能与测试系统研究［J］. 中国环境监测, 2022, 38(6): 221-227.
	Shi Y L, Wang Y, Wei L T, et al. Research on the performance of PM1 and PM2. 5 selectors and its test system ［J］. Environmental Monitoring in China, 2022, 38(6): 532-536.
	Wang T, Liu W, Zhang M T, et al. Study on functions validation of test devices for separation performance of PM2. 5 seperators ［J］. Metrology Science and Technology, 2022, 66(1): 41-45.
	Liu J Q, Zhang G C, Wu D, et al. Study on efficiency evaluation and curve fitting optimization of PM2. 5 particle separation device based on statice chamber method ［J］. Acta Metrologica Sinica, 2021, 42(10): 1398-1403.
	Chen Feng, Ji Z L, Ba Q X, et al. Oil-mist coalescence performance and optimization of filters for air filtration ［J］. Journal of chemical engineering of Chinese universities, 2022, 36(1): 101-109.
［9］	孙帅杰, 齐天缘, 肖骥, 等. 高准确度气溶胶静电计的研制及校准［J］. 计量科学与技术, 2021(2): 54-58.
	Sun S J, Qi T Y, Xiao J, et al. Development and calibration of high accuracy aerosol electrometer ［J］. Metrology Science and Technology, 2021(2): 54-58.
［11］	Yli-Ojanper J, Sakurai H, Iida K, et al. Comparison of Three Particle Number Concentration Calibration Standards Through Calibration of a Single CPC in a Wide Particle Size Range［J］. Aerosol Science and Technology, 2012(11): 1163-1173.
［13］	Iida K, Sakurai H, Ehara K. Inkjet Aerosol Generator as Monodisperse Particle Number Standard［J］. Aerosol Science and Technology, 2013, 1527: 453-456.
［15］	Mitchell J P, Waters S. Improvements to the vibrating orifice aerosol generator (VOAG) for the production of methylene blue particles［J］. Journal of Aerosol Science, 1986, 17(3): 556-560.
［3］	刘佳琪, 张国城, 赵晓宁, 等. 进气流量对PM2. 5切割器捕集效率的影响［J］. 计量学报, 2021, 42(4): 532-536.
	Liu J Q, Zhang G C, Zhao X N, et al. The influence of air inlet flow rate on the capture efficiency of PM2. 5 cutter ［J］. Acta Metrologica Sinica, 2021, 42(4): 532-536.
［8］	杨晓平. 空气净化滤材过滤性能的实验研究［J］. 价值工程, 2017(29): 148-149.
	Yang X P. Study on filtration performance of air cleaning materials ［J］. Value Engineering, 2017(29): 148-149.
［16］	ISO 21501-4: 2018, Determination of particle size distribution—Single particle light interaction methods — Part 4: Light scattering airborne particle counter for clean spaces［S］.
［17］	Vasilatou K, Waelchli C, Koust S, et al. Calibration of optical particle size spectrometers against a primary standard: Counting efficiency profile of the TSI Model 3330 OPS and Grimm 11-D monitor in the particle size range from 300nm to 10μm［J］. Journal of Aerosol Science, 2021, 157: 105818.
［19］	Vasilatou K, Wlchli C, Iida K, et al. Extending traceability in airborne particle size distribution measurements beyond 10μm: counting efficiency and unit-to-unit variability of four aerodynamic particle size spectrometers［J］. Aerosol Science and Technology, 2023, 57(1): 24-34.
［21］	Iida K, Sakurai H, Auderset K, et al. Using an inkjet aerosol generator to study particle bounce in optical particle counters［J］. Aerosol Science and Technology, 2021, 55: 1165-1182.
［1］	刘浪, 张文杰, 杜世勇, 等. 利用SPAMS分析北京市硫酸盐、硝酸盐和铵盐季节变化特征及潜在源区分布［J］. 环境科学, 2016, 37(5): 1609-1618.
［2］	张雷波, 尹立峰, 李敏姣, 等. 利用单颗粒气溶胶质谱技术研究天津市春节前后大气颗粒物粒径变化情况［J］. 天津科技, 2020, 47(4): 67-72.
［6］	刘佳琪, 张国城, 吴丹, 等. 基于静态箱法的PM2. 5切割器捕集效率评价及你和曲线优化研究［J］. 计量学报, 2021, 42(10): 1398-1403.
［7］	陈峰, 姬忠礼, 巴其鑫, 等. 空气过滤用玻璃纤维滤材的油雾聚结性能及改进优化［J］. 高等化学工程学报, 2022, 36(1): 101-109.
［12］	Kesavan J S, Bottiger J R, Schepers D R, et al. Comparison of Particle Number Counts Measured with an Ink Jet Aerosol Generator and an Aerodynamic Particle Sizer［J］. Aerosol Science and Technology, 2013(2): 219-227.
［14］	Iida K S H. Counting efficiency evaluation of optical particle counters in micrometer range by using an inkjet aerosol generator［J］. Aerosol Science and Technology: The Journal of the American Association for Aerosol Research, 2018, 52(10): 1156-1166.
［5］	王婷, 刘巍, 张明涛, 等. 切割器切割特性试验装置的功能性验证方法探讨［J］. 计量科学与技术, 2022, 66(1): 41-45.
［10］	孙帅杰, 刘俊杰, 邢化朝, 等. 气溶胶静电计的校准技术研究及方法优化［J］. 中国计量, 2017(2): 100-103.
［20］	Iida K, Sakurai H, Saito K, et al. Inkjet aerosol generator as monodisperse particle number standard［J］. Aerosol Science and Technology, 2014, 48: 789-802.
［18］	Vasilatou K, Dirscherl K, Iida K, et al. Calibration of optical particle counters: first comprehensive inter-comparison for particle sizes up to 5μm and number concentration up to 2cm-3［J］. Metrologia, 2020, 57: 1-10.