利用超重力旋轉填充床於廢資訊主機板中IC晶片碳化處理製程所排放細懸浮微粒之效能評估

Gia Han Huynh; 黃嘉欣

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/72995

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	蔣本基(Pen-Chi Chiang)
dc.contributor.author	Gia Han Huynh	en
dc.contributor.author	黃嘉欣	zh_TW
dc.date.accessioned	2021-06-17T07:13:11Z	-
dc.date.available	2024-07-23
dc.date.copyright	2019-07-23
dc.date.issued	2019
dc.date.submitted	2019-07-17
dc.identifier.citation	Agarwal, L., V. Pavani, D. P. Rao and N. Kaistha (2010). 'Process Intensification in HiGee Absorption and Distillation: Design Procedure and Applications.' Industrial & Engineering Chemistry Research 49(20): 10046-10058. Awasthi, A. K., F. Cucchiella, I. D'Adamo, J. Li, P. Rosa, S. Terzi, G. Wei and X. Zeng (2018). 'Modelling the correlations of e-waste quantity with economic increase.' Sci Total Environ 613-614: 46-53. Basu, P. (2013). 'Pyrolysis.' 147-176. Bianchini, A., M. Pellegrini, J. Rossi and C. Saccani (2018). 'Theoretical model and preliminary design of an innovative wet scrubber for the separation of fine particulate matter produced by biomass combustion in small size boilers.' Biomass and Bioenergy 116: 60-71. Bizzo, W. A., R. A. Figueiredo and V. F. de Andrade (2014). 'Characterization of Printed Circuit Boards for Metal and Energy Recovery after Milling and Mechanical Separation.' Materials (Basel) 7(6): 4555-4566. Brunekreef, B. and S. T. Holgate (2002). 'Air pollution and health.' The Lancet 360(9341): 1233-1242. Chen, Y.-S., Y.-C. Hsu, C.-C. Lin, C. Y.-D. Tai and H.-S. Liu (2008). 'Volatile Organic Compounds Absorption in a Cross-Flow Rotating Packed Bed.' Environmental Science & Technology 42(7): 2631-2636. Chu, K. W., B. Wang, D. L. Xu, Y. X. Chen and A. B. Yu (2011). 'CFD–DEM simulation of the gas–solid flow in a cyclone separator.' Chemical Engineering Science 66(5): 834-847. Deng, X., D. Tian and Y. Luo (2010). 'Experimental study of micron dust removal using high-gravity rotating bed.' Sulfuric Acid. Ind. 6: 16-20. Dominici, F., R. D. Peng, M. L. Bell, L. Pham, A. McDermott, S. L. Zeger and J. M. Samet (2006). 'Fine particulate air pollution and hospital admission for cardiovascular and respiratory diseases.' JAMA 295(10): 1127-1134. Emami Moghaddam, S. A., R. Harun, M. N. Mokhtar and R. Zakaria (2018). 'Potential of Zeolite and Algae in Biomass Immobilization.' Biomed Res Int 2018: 6563196. Fortoul, T. I., V. Rodriguez-Lara, A. Gonzalez-Villalva, M. Rojas-Lemus, L. Colin-Barenque, P. Bizarro-Nevares, I. García-Peláez, M. Ustarroz-Cano, S. López-Zepeda, S. Cervantes-Yépez, N. López-Valdez, N. Meléndez-García, M. Espinosa-Zurutuza, G. Cano-Gutierrez and M. C. Cano-Rodríguez (2015). 'Health Effects of Metals in Particulate Matter.' Fu, J., G.-S. Qi, Y.-Z. Liu, J.-X. Tian, Q. Guo and M.-Y. Dong (2015). 'Removal of ﬁne particles by high gravity wet cleaning (in Chinese).' Chem. Eng. 43: 6~10. Fu, J., G. Qi, Y. Liu, J. Tian, Q. Guo and M. Dong (2015). 'Research on removal of fine particles by cross-flow rotating packed bed.' Chem. Industry Eng. Prog 34: 680-694. Ghosh, M., D. Sur, S. Basu and P. S. Banerjee (2018). 'Metallic Materials From E-Waste.' Guo, J., J. Guo and Z. Xu (2009). 'Recycling of non-metallic fractions from waste printed circuit boards: a review.' J Hazard Mater 168(2-3): 567-590. Hakobyan (2015). 'Introduction to basics of submicron aerosol particles ﬁ ltration theory via ultra ﬁne ﬁber media. .' Armenian J Phys 8(3): 140 – 151. Hu, X.-P., D.-L. Tian and X.-H. Deng (2009). 'Experimental research on removing of micron scale dust by high gravity rotating packed bed (in Chinese).' Mod. Chem. Ind. 29: 69-74. Huang, D.-B., X.-H. Deng, D.-L. Tian and X.-P. Hu (2011). 'Experimental research on removal of micron level dust by high gravity rotating packed bed.' Huaxue Gongcheng/Chemical Engineering (China) 39(3): 42-45. Ikhlayel, M. (2017). 'Environmental impacts and benefits of state-of-the-art technologies for E-waste management.' Waste Manag 68: 458-474. Kim, J. W., A. S. Lee, S. Yu and J. W. Han (2018). 'En masse pyrolysis of flexible printed circuit board wastes quantitatively yielding environmental resources.' J Hazard Mater 342: 51-57. Li, J., H. Duan, K. Yu, L. Liu and S. Wang (2010). 'Characteristic of low-temperature pyrolysis of printed circuit boards subjected to various atmosphere.' Resources, Conservation and Recycling 54(11): 810-815. Li, J. H. and Y. Z. Liu (2007). 'Experimental study of removal dust from flue gas by high gravidity technology and its mechanism.' Chem. Prod. Technol. 14: 35-37. Li, W., X. Wu, W. Jiao, G. Qi and Y. Liu (2017). 'Modelling of dust removal in rotating packed bed using artificial neural networks (ANN).' Applied Thermal Engineering 112: 208-213. Liu, Y., Y. Luo, G.-W. Chu, J.-Z. Luo, M. Arowo and J.-F. Chen (2017). '3D numerical simulation of a rotating packed bed with structured stainless steel wire mesh packing.' Chemical Engineering Science 170: 365-377. Lu, H.-Y., S.-L. Lin, J. K. Mwangi, L.-C. Wang and H.-Y. Lin (2016). 'Characteristics and Source Apportionment of Atmospheric PM2.5 at a Coastal City in Southern Taiwan.' Aerosol and Air Quality Research 16(4): 1022-1034. Luo, Y., J.-Z. Luo, G.-W. Chu, Z.-Q. Zhao, M. Arowo and J.-F. Chen (2017). 'Investigation of effective interfacial area in a rotating packed bed with structured stainless steel wire mesh packing.' Chemical Engineering Science 170: 347-354. Miller, B. G. (2017). 'Particulate Formation and Control Technologies.' 419-465. Milligan, M. S. A., E. (1993). 'The Relationship between de Novo Synthesis of Polychlorinated Dibenzo-p-dioxins and Dibenzofurans and Low-Temperature Carbon Gasification in Fly Ash.' Environmental Science and Technology 27(1595-1601). Montgomery, D. (2001). Design and Analysis of Experiments (fifth edition), John Wiley and Sons. Nakamura, H., N. Deguchi and S. Watano (2015). 'Development of tapered rotating fluidized bed granulator for increasing yield of granules.' Advanced Powder Technology 26(2): 494-499. Ortuño, N., J. Moltó, S. Egea, R. Font and J. A. Conesa (2013). 'Thermogravimetric study of the decomposition of printed circuit boards from mobile phones.' Journal of Analytical and Applied Pyrolysis 103: 189-200. Pan, S.-Y., P. Wang, Q. Chen, W. Jiang, Y.-H. Chu and P.-C. Chiang (2017). 'Development of high-gravity technology for removing particulate and gaseous pollutant emissions: Principles and applications.' Journal of Cleaner Production 149: 540-556. Pei, S. L., S. Y. Pan, Y. M. Li and P. C. Chiang (2017). 'Environmental Benefit Assessment for the Carbonation Process of Petroleum Coke Fly Ash in a Rotating Packed Bed.' Environ Sci Technol 51(18): 10674-10681. Perkins, D. N., M. N. Brune Drisse, T. Nxele and P. D. Sly (2014). 'E-waste: a global hazard.' Ann Glob Health 80(4): 286-295. Ramshaw, C. (2008). 'A brief history of process intensification.' 1-20. Sang, L., Y. Luo, G.-W. Chu, J.-P. Zhang, Y. Xiang and J.-F. Chen (2017). 'Liquid flow pattern transition, droplet diameter and size distribution in the cavity zone of a rotating packed bed: A visual study.' Chemical Engineering Science 158: 429-438. Song, Y., J. Chen, J. Fu and J. Chen (2003). 'Research on particle removal efficiency of the rotating packed bed.' Chem. Industry Eng. Prog. 22: 499-502. Teuten, E. L., J. M. Saquing, D. R. Knappe, M. A. Barlaz, S. Jonsson, A. Bjorn, S. J. Rowland, R. C. Thompson, T. S. Galloway, R. Yamashita, D. Ochi, Y. Watanuki, C. Moore, P. H. Viet, T. S. Tana, M. Prudente, R. Boonyatumanond, M. P. Zakaria, K. Akkhavong, Y. Ogata, H. Hirai, S. Iwasa, K. Mizukawa, Y. Hagino, A. Imamura, M. Saha and H. Takada (2009). 'Transport and release of chemicals from plastics to the environment and to wildlife.' Philos Trans R Soc Lond B Biol Sci 364(1526): 2027-2045. Wang, Z., T. Yang, Z. Liu, S. Wang, Y. Gao and M. Wu (2019). 'Mass Transfer in a Rotating Packed Bed: A Critical Review.' Chemical Engineering and Processing - Process Intensification 139: 78-94. Weil, E. D. and S. Levchik (2016). 'A Review of Current Flame Retardant Systems for Epoxy Resins.' Journal of Fire Sciences 22(1): 25-40. Xie, P., X. Lu, H. Ding, X. Yang, D. Ingham, L. Ma and M. Pourkashanian (2019). 'A mesoscale 3D CFD analysis of the liquid flow in a rotating packed bed.' Chemical Engineering Science 199: 528-545. Xie, P., X. Lu, X. Yang, D. Ingham, L. Ma and M. Pourkashanian (2017). 'Characteristics of liquid flow in a rotating packed bed for CO 2 capture: A CFD analysis.' Chemical Engineering Science 172: 216-229. Yan, Z.-y., C. Lin and Q. Ruan (2012). 'Hydrodynamics in a Rotating Packed Bed. I. A Novel Experimental Method.' Industrial & Engineering Chemistry Research 51(31): 10472-10481. Zou, H.-K., M. Arowo, Q. Zhang, L. Zhang, B. Sun, G.-W. Chu, L. Shao and J.-F. Chen (2018). 'Flue-Gas Desulfurization by Using a HiGee Electric-Field Device.' Chemical Engineering & Technology 41(4): 860-866.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/72995	-
dc.description.abstract	隨著科技進步及人們消費模式改變，電子廢棄物日益地增加，不僅造成大量的物質之浪費，且造成許多環境污染議題。本研究利用此類的廢棄物藉由高溫碳化過程，結合使用優勝奈米公司所研發的環保剝金技術進行高效回收金製程。電子廢棄物經過高溫碳化過程中會產生對人體有害之細懸浮微粒，而旋轉填充床藉由高速旋轉，增加微小液滴及液膜，增加與懸浮微粒碰撞的機率，從此提升捕捉效果。本研究之主要目的為優化各製程的操作參數。首先，碳化製程必須考量金最佳提取率及污染排放最小化。從實驗結果，本研究得出優化條件出現於800oC，金之提取率可高達99.8%。除此以外，超重力技術透過反應曲面法可找出最高效率之操作條件，本研究最高去除效率可達至99.2% 當超重力因子為323及氣液比約 4.22。除了實際操作以外，本研究集合多項經驗公式及實際操作條件，透過建立半理論模式進行探討每種去除機制在不同懸浮微粒粒徑分佈下之貢獻量。最後，本研究針對空氣污染物排及能源議題進行整合性分析，因此可得出該整合性技術之實際最佳操作條件。	zh_TW
dc.description.abstract	The urban mining via electronic waste (e-waste) recycling process is a merging industries which several high-value precious metals can be collected to reduce natural degradation and depletion. To obtain those precious metals more effective, the e-waste pretreatments such as carbonization process are inevitable. In this study, the high-gravity rotating packed bed (HiGee RPB) was applied to grade down the air pollution, especially fine-sized particles due to its centrifugal force, also micro-mixing performance between gas and liquid phase. The carbonization process was considered to balance and qualify two conditions, including maximal of gold stripping efficiency with minimal of PM emission. The optimized condition was achieved at 800oC with the gold stripping efficiency reached up to 99.8%. Besides, the countercurrent RPB was operated to proceed on-site experiment under different operating condition such as high gravity factor and gas-to-liquid ratio. By using response surface method (RSM), the maximal achievable removal efficiency (MARE) was identified as 99.2% when high gravity of 323, gas-to-liquid ratio of 4.22. Moreover, empirical and semi-theoretical were developed basing on experiment results as well as several physical variables. Remarkably, the semi-theoretical was established to describe how the Brownian diffusion, inertial impaction as well as interception affect the removal efficiency in different size of particles. The U-shaped curve was determined with a minimum in the region around 1.9 µm. Finally, the concept of particles capture capacity was applied to illustrate the air-energy nexus issue. A motivation toward a cleaner production technology with the integration of carbonization process and high gravity RPB system was described with the expectedly providing a reference for optimizing design, or scaling up, also promising solution for efficient e-waste carbonization as well as particles emission controls in the future.	en
dc.description.provenance	Made available in DSpace on 2021-06-17T07:13:11Z (GMT). No. of bitstreams: 1 ntu-108-R06541139-1.pdf: 5174051 bytes, checksum: e0630d45fca04d0e2b0c4abeb5b45bd5 (MD5) Previous issue date: 2019	en
dc.description.tableofcontents	誌謝 II 中文摘要 III Abstract IV Oral Defense Comments XIII Chapter 1 Introduction 1-1 1.1. Background 1-1 1.2. Objectives 1-4 Chapter 2 Literature Review 2-1 2.1. Waste Electrical and Electronic Equipment (WEEE) 2-1 2.1.1. Current E-waste Recycling Technology 2-1 2.1.2. Challenges Linked with E-waste: Carbonization 2-8 2.1.3. E-waste Gold Stripping Method 2-13 2.2. Physicochemical Characteristics of Particulate Matters 2-16 2.2.1. Physical and Size Distribution of Airborne Particles 2-16 2.2.2. Chemical Properties of Particulate Matters 2-17 2.2.3. Exposure and Impacts 2-19 2.3. The Removal Mechanism of Particulate Matters 2-22 2.3.1. Interception 2-24 2.3.2. Inertial Impaction 2-25 2.3.3. Brownian Diffusion 2-26 2.4. HiGee Technology: Principles and Practices 2-27 2.4.1. Working Principles 2-28 2.4.2. Performance of Particulate Matter Removal via RPB 2-30 2.4.3. Flow Pattern and Modeling 2-35 Chapter 3 : Materials and Methods 3-1 3.1. Research Flowchart 3-1 3.2. Experimental Materials 3-2 3.2.1. Materials 3-2 3.2.2. Apparatus 3-3 3.3. Methods 3-6 3.3.1. Experimental Design 3-6 3.3.2. Determination of Gold Stripping Efficiency 3-8 3.3.3. Fine Particles Removal Efficiency 3-10 3.3.4. Optimization of Achievable Removal Efficiency 3-13 3.4. Analytical Methods 3-14 3.1.1. Inductive Coupled Plasma-Optical Emission Spectroscopy (ICP-OES) 3-14 3.1.2. Scanning Electron Microscopy (SEM) 3-14 3.1.3. Thermogravimetric Analysis (TGA) 3-15 Chapter 4 : Results and Discussion 4-1 4.1. Performance Evaluation of Carbonization Process 4-1 4.1.1. The Effect of Temperature on Gold Stripping Process 4-1 4.1.2. The Physicochemical Properties of PM Emitted from IC Carbonization 4-10 4.1.3. Summary 4-16 4.2. Performance Evaluation of PM removal by Rotating Packed Bed 4-18 4.2.1. The Effect of High Gravity Factor 4-18 4.2.2. The Effect of Liquid and Gas Flow rate 4-22 4.2.3. Determination of Maximal Achievable Removal Efficiency (MARE) 4-29 4.2.4. Summary 4-34 4.3. Model Development 4-36 4.3.1. Empirical Model of Fine Particle Removal Efficiency 4-36 4.3.2. Semi-theoretical Model of Fine Particle Removal Efficiency 4-39 4.3.3. Summary 4-51 4.4. Comprehensive Assessment of E-waste Recycling Process 4-52 4.4.1. Energy Consumption for Particles Removal Process 4-52 4.4.2. The Optimization of Waste-to-Energy Gold Recycling Process 4-55 4.4.3. Summary 4-60 Chapter 5 : Conclusions and Recommendations 5-1 5.1. Conclusions 5-1 5.2. Recommendations 5-3 References 1
dc.language.iso	en
dc.subject	細懸浮微粒減量	zh_TW
dc.subject	IC晶片碳化製程	zh_TW
dc.subject	旋轉填充床	zh_TW
dc.subject	空污 - 能源鏈結	zh_TW
dc.subject	fine particles reduction	en
dc.subject	air-energy nexus	en
dc.subject	rotating packed bed	en
dc.subject	IC chip carbonization	en
dc.title	利用超重力旋轉填充床於廢資訊主機板中IC晶片碳化處理製程所排放細懸浮微粒之效能評估	zh_TW
dc.title	Performance Evaluation of Fine Particles Removal from Waste IC Board Carbonization Process via a Rotating Packed Bed	en
dc.type	Thesis
dc.date.schoolyear	107-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	顧洋,陳奕宏,林逸彬,潘述元
dc.subject.keyword	細懸浮微粒減量,IC晶片碳化製程,旋轉填充床,空污 - 能源鏈結,	zh_TW
dc.subject.keyword	fine particles reduction,IC chip carbonization,rotating packed bed,air-energy nexus,	en
dc.relation.page	128
dc.identifier.doi	10.6342/NTU201901375
dc.rights.note	有償授權
dc.date.accepted	2019-07-18
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	環境工程學研究所	zh_TW
顯示於系所單位：	環境工程學研究所

文件中的檔案：

檔案	大小	格式
ntu-108-1.pdf 未授權公開取用	5.05 MB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。