• |本期目錄/Table of Contents|

    [1]舒霞云,吳常健,常雪峰,等.氣溶膠噴射打印系統成形寬度影響因素分析[J].廈門理工學院學報,2020,(3):1-8.[doi:doi:1019697/jcnki16734432202003001]
     SHU Xiayun,WU Changjian,CHANG Xuefeng,et al.Influence Factors of Line Width by Aerosol Jet Printing System[J].Journal of JOURNAL OF XIAMEN,2020,(3):1-8.[doi:doi:1019697/jcnki16734432202003001]
    點擊復制

    氣溶膠噴射打印系統成形寬度影響因素分析(PDF)
    分享到:

    《廈門理工學院學報》[ISSN:1673-4432/CN:35-1289/Z]

    卷:
    期數:
    2020年第3期
    頁碼:
    1-8
    欄目:
    機械與汽車工程
    出版日期:
    2020-06-30

    文章信息/Info

    Title:
    Influence Factors of Line Width by Aerosol Jet Printing System
    文章編號:
    16734432(2020)03000108
    作者:
    舒霞云12吳常健12常雪峰12張曉城12劉波12
    (1福建省精密驅動與傳動高校重點實驗室,福建 廈門 361024; 2廈門理工學院機械與汽車工程學院,福建 廈門 361024)
    Author(s):
    SHU Xiayun12 WU Changjian12 CHANG Xuefeng12 ZHANG Xiaocheng12 LIU Bo12
    (1. FujianKey Laboratory of Precision Actuation and Transmission, Xiamen 361024, China 2. School of Mechanical & Automotive Engineering, Xiamen University of Technology, Xiamen 361024, China)
    關鍵詞:
    氣溶膠噴射打印系統成形寬度控制變量法納米銀導電油墨單參量對比實驗
    Keywords:
    aerosol jet printing system printed line width control variable method nano silver conductive ink singleparameter contrast test
    分類號:
    TS8535;TP602
    DOI:
    doi:1019697/jcnki16734432202003001
    文獻標志碼:
    A
    摘要:
    在分析氣溶膠噴射打印技術工作原理的基礎上,利用商用壓電陶瓷霧化片和自行設計制造的噴印頭,構建出由氣溶膠噴射打印裝置、溫度控制裝置和運動控制裝置3部分構成的氣溶膠噴射打印系統。以納米銀導電油墨為對象,采用單參量對比實驗分析法,研究鞘氣流量、載氣流量、噴嘴與襯底間距、打印速度、打印層數等因素對打印成形寬度的影響。結果表明:隨著載氣流量增大、層數增加,納米銀導電油墨沉積成形寬度增加;在實驗參數范圍內,載氣流量和打印層數對成形線寬影響明顯,且呈正相關;線寬隨著鞘氣流量的增大先減小后增大;噴嘴與襯底間距在15~45 mm范圍內對線寬無明顯影響;在噴嘴直徑為200 μm,鞘氣流量為50 mL·min-1,載氣流量為3 mL·min-1,噴嘴與襯底間距為3 mm,襯底移動速度為3 mm·s-1,打印層數為6~8層,加熱板溫度為80 ℃時,可獲得最小寬度為26 μm,高度為7 μm的均勻線條,這也是納米銀導電油墨噴射打印的最優工藝參數。
    Abstract:
    In this paper,a homemade aerosol jet printing system consisting of an aerosol jet printing device,temperature control and motion control was constructed using a commercial piezoelectric ceramic and a selfmade inkjet head,and influence factors of width printed was studied applying nano silver conductive ink printing system and parameters of sheath gas flow,carrier gas flow,nozzlesubstrate distance,printing speed and printing layers.Results show that the deposited line width of nano silver conductive ink increases with the increase of carrier gas flow and layers and,within the range of the parameters involved,carrier gas flow and number of layers have a positive and positive correlation with the line width formed,the line width decreases and then increases with the increase of the sheath gas flow,and the nozzlesubstrate distance at 1.5~4.5 mm shows no significant influence on the line width formed.Results also show that uniform line at width of 26 micrometers and height of 7 micrometers was printed with optimized parameters of 200 micrometers in nozzle diameter,50 milliliter per minute in sheath gas flow rate,3 milliliter per minute in carrier gas flow rate,3 mm in nozzletosubstrate distance,3 millimeters per second in substrate moving speed,68 printing layers,and 80 ℃ substrate temperature,which proves the optimal parameters of nano silver conductive ink jet printing.

    參考文獻/References:

    [1] METTE A,RICHTER P L,HRTEIS M,et al.Metal aerosol jet printing for solar cell metallization[J].Progress in Photovoltaics: Research and Applications,2007,15(7): 621627. [2] SALARY R,LOMBARDI J P,SAMIE T M,et al.Computationalfluid dynamics modeling and online monitoring of aerosol jet printing process[J].Journal of Manufacturing Science and Engineering,2017,139(2):021015. [3] FENG J Q.A computational study of highspeed microdroplet impact onto a smooth solid surface[J].Journal of Applied Fluid Mechanics, 2017,10(1):243256. [4] CHEN G,GU Y,TSANG H,et al.The effect of droplet sizes on overspray in aerosoljet printing[J].Advanced Engineering Materials,2018,20(8): 1701084. [5] BINDER S,GLATTHAAR M,EDDA R.Analytical investigation of aerosol Jet printing[J].Aerosol Science & Technology,2014,48(9):924929. [6] ECKSTEIN R,HERNANDEZ S G,LEMMER U,et al.Aerosol jet printed top grids for organic optoelectronic devices[J].Organic Electronics,2014,15(9):2 1352 140. [7] GUPTA A A,BOLDUC A,CLOUTIER S G,et al.Aerosol jet printing for printed electronics rapid prototyping[C]//IEEE International Symposium on Circuits and Systems (ISCAS).Montreal:IEEE,2016: 866869. [8] SEIFERT T,BAUM M,ROSCHER F,et al.Aerosol jet printing of nano particle based electrical chip interconnects [J].Materials Today Proceedings,2015,2(8):4 2624 271. [9] 汪駿雄.基于聲表面波的微流體霧化機理與實驗研究[D].哈爾濱:哈爾濱工業大學,2016. [10] 江峰.壓電陶瓷超聲霧化器研究[D].南京:南京航天航空大學,2014.

    相似文獻/References:

    備注/Memo

    備注/Memo:
    收稿日期:20191226修回日期:20200215 基金項目:福建省自然科學基金項目(2017J01492);國家自然科學基金項目(51975501) 通信作者:舒霞云,男,副研究員,博士,研究方向為微納增材制造技術、精密超精密加工,Email:shuxiayun@xmut.edu.cn。 引文格式:舒霞云,吳常健,常雪峰,等.氣溶膠噴射打印系統成形寬度影響因素分析[J]廈門理工學院學報,2020,28(3):18 Citation:SHU X Y, WU C J, CHANG X F,et al.Influence factors of line width by aerosol jet printing system[J]Journal of Xiamen University of Technology,2020,28(3):18(in Chinese)
    更新日期/Last Update:
    大佬彩票平台