- 學位論文
奈米金銀及甲殼素活性碳之濾網吸附動力模式
A study of adsorption dynamic model of nano Au, Ag, Chitosan coated activated carbon filters
摘要
市面上各種濾網移除空氣污染物之技術各有優缺點。本研究針對氣狀污染物(甲醛、丙酮、一氧化碳)和生物性氣膠(真菌、細菌)作進一步探討。使用活性碳濾網並添加奈米金銀、奈米銀、和幾丁聚醣,由實驗設計之系統測試去除效率和吸附量,另將實場檢測結果與實驗做比較。本研究採用擬一階吸附動力模式及擬二階吸附動力模式兩種方法,分別進行各濾網對空氣污染物之模擬與探討,以求得較適合模擬之吸附動力式。 實驗結果,添加幾丁聚醣(chitosan)有效增加甲醛之去除率 (16.33%)、丙酮和一氧化碳則不明顯;添加奈米金銀(Au-Ag)增加甲醛之去除率(20 %)一氧化碳之去除率(7.11%),丙酮則不明顯。 實場檢測,停車場測試結果,添加奈米金銀增加一氧化碳之去除效率(7.48 %)。添加奈米銀增加細菌之去除效率(19.57 %),添加幾丁聚醣增加真菌(17.1%)、細菌(35 %)之去除率。幼稚園測試結果,添加奈米金銀增加甲醛之去除率(9.02%),添加幾丁聚醣有效增加甲醛之去除率 (42%)。 吸附動力模式模擬結果,甲醛、丙酮及一氧化碳吸附較吻合擬二階吸附動力模式。此外,添加奈米金銀、奈米銀有助於提高濾網對甲醛、丙酮和一氧化碳之吸附量。
並列摘要
There are many advantages and disadvantages of filters technologies of removal air pollutants in the market. The study focuses on gaseous pollutants such as Formaldehyde (HCHO), Volatile Organic Compounds, VOC (C3H6), Carbon monoxide (CO) and bioaerosol (Bacteria and fungi) . To take activated carbon filters added nano gold (Au)- silver (Ag) , nano Ag and chitosan , tested removal efficiency and adsorption capacity by experimental studies. Moreover ,To be compared with the field studies and experiment studies. The study simulated and discuss air pollutants by used pseudo-first-order model and pseudo-second-order model , in order to achieve appropriate simulation. The experimental results showed that the removal efficiency of HCHO was increased by 16.33% when chitosan added , but not obvious on VOCs and CO. The removal efficiency of both HCHO and CO were increased by 20% and 7.11% when nano Au-Ag added in activated carbon filter. The parking lot studies showed the removal efficiency of CO was increased by 7.48% when nano Au-Ag added in activated carbon filter. The removal efficiency of Bacteria was increased by 19.57% , Fungi was increased by 17.1% when nano Ag added in activated carbon filter, the removal efficiency of Bacteria was increased by 35% when chitosan added. The kindergarten (KG) studies the removal efficiency of HCHO was increased by 9.02% when nano Au-Ag added in activated carbon filter. The removal efficiency of HCHO was increased by 42% when chitosan added in activated carbon filter. Adsorption dynamic model results HCHO 、 C3H6 and CO coincided pseudo-second-order model, it is effectively increased HCHO ,C3H6, CO adsorption capacity by added nano Au-Ag and nano Ag.
參考文獻
延伸閱讀
- Kuo, H. F. (2007). 奈米碳管之功能化:表面修飾與摻雜效應 [doctoral dissertation, National Tsing Hua University]. Airiti Library. https://doi.org/10.6843/NTHU.2007.00248
- 卓裕盛、連興隆(2005)。奈米級零價鐵金屬去除混合性污染物之研究。界面科學會誌,27(1),55-63。https://doi.org/10.30020/JCCIS.200503.0006
- 陳楷傑(2015)。奈米矽片銀改質濾材控制室內生物氣膠之研究〔碩士論文,國立臺灣大學〕。華藝線上圖書館。https://doi.org/10.6342/NTU.2015.00157
- Ashrafi, F., Ghasemi, A., Babanejad, S., & Rahimof, M. (2010). Optimization of Carbon Nanotubes for Nitrogen Gas Adsorption. Research Journal of Applied Sciences, Engineering and Technology, 2(6), 547-551. https://www.airitilibrary.com/Article/Detail?DocID=20407467-201009-201411050018-201411050018-547-551
- 陳怡君(2019)。Preparation of porous activated carbon from waste sponge : study of sorption model and application〔碩士論文,中山醫學大學〕。華藝線上圖書館。https://doi.org/10.6834/CSMU201900262