簡易式微細氣泡柱運用於畜舍空氣除塵之可行性研究

Yin-Chieh Lu; 呂盈潔

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/40390

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	侯文祥
dc.contributor.author	Yin-Chieh Lu	en
dc.contributor.author	呂盈潔	zh_TW
dc.date.accessioned	2021-06-14T16:46:25Z	-
dc.date.available	2010-08-06
dc.date.copyright	2008-08-06
dc.date.issued	2008
dc.date.submitted	2008-07-30
dc.identifier.citation	Aarnink, A. J. A. and M. J. M. Wagemans. 1997. Ammonia vitalization and dust concentration as affected by ventilation systems in houses for fattening pigs. Transactions of the ASAE. Vol.40(4): 1161-1170. ADAS Technical Services Division. 1981. Concentration of airborne dust in intensive poultry units. Project 02128, MAFF Commission Review. 52. Almuhanna, E. 2007. Dust control in livestock buildings with electrostatically charged water spray. PhD Diss. Manhattan, Kans.: Kansas State University. Atia, A. E. 1995. Air cleaning system for livestock buildings. Ph.D. Dissertation. Ames, IA: Iowa State University. Bottcher, R., R. Munilla, G. Baughman and K. Keener. 2000. Designs for windbreak walls for mitigating dust and odor emissions from tunnel ventilated swine buildings. North Carolina State University. Bundy, D. S. and T. E. Hazen. 1973. Particle-size characterization of dust in swine confinement systems. ASAE Paper No. MC-73-501. St. Joseph, MI: ASAE. Bundy, D. S. 1984. Rate of dust decay as affected by relative humidity, ionization, and air movement. Trans. ASAE. Vol.27(3): 865-870. Calabrese, R. V., T. P. K. Chang and P. T. Dang. 1986. Drop breakup in turbulent stirred-tank contactors. Part I: Effect of dispersed-phase viscosity. AIChE Journal. Vol.32:657–666. Cargill, C., T. Banhazi and I. Connaughton. 1997. Converting existing continuous flow production to all-in/all-out: health, production and financial implications. In Proceedings of the AAVP Conference, Brisbane, Australia. Sydney, Australia: Pharmacia Animal Health. Carpenter, G. A. 1982. The design of an internal ceiling-mounted air filter unit and its application in an early-weaner unit. Division Note DN/1128,National Institute Agriculture Engineering,Silsoe. Cermak, J. P. 1976. The stockman's work. Pig housing supplement. Pig Farming Dec 1976:75-81. Cermak, J. P. and P. A. Ross. 1978. Airborne dust concentrations associated with animal housing tasks. Farm Building Progress. Vol.51:11-15. Chen, S. 1991. Theoretical and experimental investigation of foam separation applied to aquaculture. Ph.D. dissertion, Cornell Univ., Ithaca, NY:239. Chen, W. K. 1997.Removal of Particles from a recirculative eel culture system by foam separation. Thesis for Master of Science. National Taiwan University. Cramers, P. H. M. R., A. A. C. M. Beenackers and L. L. van Dierendonck. 1992. Hydrodynamics and mass transfer characteristics of a loop-venturi reactor with a downflow liquid jet ejector. Chemical Engineering Journal. Sci. Vol.47(13/14):3557-3564. Cramers, P. H. M. R. and A. A. C. M. Beenackers. 2001. Influence of the ejector configuration, scale and the gas density on the mass transfer characteristics of gas-liquid ejectors. Chemical Engineering Journal. Vol.82(3):131-141. Cunningham, R. G. and R. J. Dopkin. 1974. Jet breakup and mixing throat lengths for the liquid jet gas pump. ASME Journal of Fluids Engineering. Vol.96(3):216-226. Davis, M. L. and D. A. Cornwell. 1991. Introduction to environmental engineering. New York. NY: McGraw-Hill, Inc. Donham, K. J., L. I. Scallion, W. Popendorf, M. W. Fruehauf and R. C. Roberts. 1986. Characterization of dusts collected from swine confinement buildings. American Industrial Hygiene Association Journal. Vol.47(7):404-410. Feng, D. and Aldrich. 1999. Effect of particle size on flotation performance of complex sulfide ores. Miner. Eng. Vol.12(7):721-731. Feng, Q. M., X. Mu, G. F. Zhang, Y. P. Lu; L. M. Ou, Y. H. Shao and Y. Chen. 2005. Investigation on antifoaming of flotation bauxite. Journal of Central South University of Technology(Natural Science).Vol.36(6):955~959 Hammond, E. G., C. Fedler, and G. Junk. 1979. Identification of dust-borne odors in swine confinement facilities. Trans. of the ASAE. Vol.22:1186-1189. Hangartner, M. 1985. Selection and treatment of panelists for determination of odor thresholds. In: Odor Prevention and Control of Organic Sludge and Livestock Farming. Edt: Nielsen, V. C., Voorburg, J.H. and I’Hermite, P. Elsevier Applied Science. New York, NY:55-60. Hartung, J. 1994. The effect of airborne particulates on livestock health and production. In Poll. in Livestock Prod. Systems, eds. I. Ap Dewi, R. F. E. Axford, I. Fayez, M. Marai and H. M. Omed, 55-69. Wallingford, Oxon, U.K.: CAB International. Heber, A. J. and C. R. Martin. 1988. Effect of additives on aerodynamic segregation of dust from swine feed. Trans. of the ASAE. Vol.31(2):558-563. Hillman, P., K. Gebremedian, and R. Warner. 1992. Ventilation system to minimize airborne bacteria, dust, humidity, and ammonia in calf nurseries. Journal of Dairy Sciences. Vol.75(5):1305-1312. Honey, L. F. and J. B. McQuitty. 1979. Some physical factors affecting dust concentrations in a pig facility. Can. Agric. Eng. Vol.21(1):9-14. Jacobson, L., L. Johnston, B. Hetchler, and K. Janni. 1999. Odor emission control by sprinkling oil for dust reduction in pig buildings. In Dust Control in Animal Production Facilities, Proc. Congress in Aarhus, Denmark, 30 May-2 June, 223-230. Horsens, Denmark: Danish Institute of Agricultural Sciences, Research Centre Bygholm. Jagielo, P. J., P. S. Thorne, J. L. Watt, K. L. Frees, T. J. Quinn, and D. A. Schwartz. 1996. Grain dust and endotoxin inhalation challenges produce similar inflammatory responses in normal subjects. Chest 110:263-270. Ji, Y. O., H. O. Wang and A. O. Qi. 2005. Study of measuring micro2bubble diameter. Journal of Experiments in Fluid Mechanics. Vol.19(2):51-53 Lee, C. W. 2007. Study of eliminating ammonia of pig house with bubble column. Thesis for Master of Science. National Taiwan University. Lu, Y. J. and X. H. Zhu. 2001. Trend of the solvent sublation technique. Progress in Chemistry. Vol.3(6):441-449 Marrufo Villa, D., L. J. A. Quintana and S. M. P. Castaneda. 1999. Effect of positive pressure ventilation on production parameters of broiler fowls in a natural environment house. Veterinaria (Mex. City). Vol.30:99-103. Muller, W. and P. Wieser. 1987. Dust and microbial emissions from animal production. In: Animal production and environmental health, D. Strauch (ed), pp.47-89. New York, NY: Elsevier Science Publishers. Nonnenmann, M. W., R. H. Rautiainen, K. J. Donham, S. P. Kirychuk, S. J. Reynolds, P. T. O´Shaughnessy and P. S. Thorne. 1999. Vegetable oil sprinkling as a dust reduction method in a swine confinement. In Dust Control in Animal Production Facilities, Proc. Congress in Aarhus, Denmark, 30 May-2 June, 271-285. Horsens, Denmark: Danish Institute of Agricultural Sciences, Research Centre Bygholm. Pearson, C. C. 1987. A wet scrubber for control of aerial pollution in intensive livestock housing. In Pig Housing and the Environment, ed. A. T. Smith and T. L. J. Lawrence, 141. British Society of Animal Production. Pearson, C. C. and T. J. Sharples. 1995. Airborne dust concentration in livestock buildings and the effect of feed. J. agric. Engng Res. 60: 145-154. Pedersen, S. 1993. Time based variation in airborne dust in respect to animal activity. In Livestock Environment IV. Proc. 4th Int. Livestock Environment Symp., 718-725. St. Joseph, Mich.: ASAE. Predicala, B. Z. 2003. Characterization and modeling of particulate matter emissions within and from swine buildings. Ph.D. Dissertation. Manhattan, KS: Kansas State University. Qu, Y. P., H. G. Du, L. J. Ge. 2002. Effects of surface viscosity on foam stability.Vol24(4):283-286 Ralston, J. and S. S. Dukhin. 1999. Interaction between particles and bubbles. Colloids and Surfaces A: Physicochemical and Engineering Aspects. Vol.151: 3–14. Robertson, I. H. and W. R. Frieben. 1984. Microbial validation of vent filter. Biotechnology and Bioengineering. Vol.26:828-835. Rosen, M. J. 1989. Surfactants and interfacial phenomena. 2nd Ed. New York: Wiley-Interscience; pp. 393–419. Rylander, R., B. Bake, J. J. Fischer and I. M. Helander. 1989. Pulmonary function and symptoms after inhalation of endotoxin. Am. Rev. Respir. Dis. 140:981-986. Snell, H. G.. J. and A. Schwarz. 2003. Development of an efficient bioscrubber system for the reduction of emissions. ASAE Paper No. 034053. St. Joseph, Mich.: ASAE. Smith, J. S. and K. T. Valsaraj. 1997. Industrial and Engineering Chemistry Research. 36:903—914 Smorodin, V., W. Balachandran and C. Hudson. 1999. Study of indoor aerosol removal with electro-spray. Electrostatics '99, Institute of Physics Conference Series. 163:421-424. Spoolder, H. A., S. A. Edwards and S. Corning. 2000. Aggression among finishing pigs following mixing in kennelled and unkennelled accommodation. Livestock Production Science. Vol.63(2):121-129. Takai, H., S. Pedersen, J. O. Johnsen, J. H. M. Metz, P. W. G. Groot Koerkamp, G. H. Uenk, V. R. Phillips, M. R. Holden, R. W. Sneath, J. L. Short, R. P. White, J. Hartung, J. Seedorf, M. Schroder, K., H. Linkert and C. M. Wathes. 1998. Concentrations and emissions of airborne dust in livestock buildings in Northern Europe. Journal of Agricultural Engineering Research. Vol.70(1):59-77. Takai, H. and S. Pedersen. 2000. A comparison study of different dust control methods in pig buildings. Applied Engineering in Agriculture. Vol.16(3): 269-. Tao, D. 2005. Role of bubble size in flotation of coarse and fine particles—a review. Separation Science and Technology. Vol.39(4): 741–760. Thome, P. S., M. S. Kiekhaefer, P. Whitten and K. J. Donham. 1992. Comparison of bioaerosol sampling methods in barns housing swine. Applied and Environmental Microbiology. Vol.58(8):2543-2551. Tsai , T. L. 2003. Development of simple microbubble generated device and its application on ozonation and oxygenation of fresh and sea water. Thesis for Master of Science. National Taiwan University. Vinzents, P. and H. Christensen. 1990. Arbejdsmiljø ved svineavl (Work environment on pig breeding). Copenhagen, Denmark: Danish National Institute of Occupational Health. Wang, J.H. 2001. Influence of operational parameters of bubble column on particle and dissolved inorganic nitrogen removal in recirculating fresh water and seawater. Thesis for Master of Science. National Taiwan University. Whyte, R.T. 1993. Aerial pollutants and health of poultry farmers. World's Poultry Science Journal. Vol.49:139-156. Williams, A. G. 1989. Dust and odor relationships in broiler house air. J. Agric. Eng. Res. 44:175–190. Witte, J.H. 1969. Mixing shock in two phase flow. Journal of Fluid Mechanics Vol.36:639–655. Xu, J. 2002. Compounding of defoamers and probing into deforming mechanisms. China Beet & Sugar. Vol.4:31-34 Xu, S. Y., J. J. Chen and D. R. Cao. 2006.Analysis of components in wood vinegar. Guangzhou Chemistry. Vol.31(3):28-31 Yeh, H. C. 2006. The standardization and the application research of the simple microbubble generated device. Thesis for Master of Science. National Taiwan University. Yoon, R. H. and G. H. Luttrell. 1989 The effect of bubble size on fine particle flotation. Miner. Process. Extr. Metall. Rev. 5:101-122. Yu, S. P., Z. Y. Zhang, X. J. Fan. 1994. The half-life time of the foams formed with various surfactant systems at acidic ph values. Vol.11(1):70-73 Zhang, R. S., Y. Zheng, Y. S. Cheng. 2005. Study of measuring microbubble diameter. Journal of Experiments in Fluid Mechanics. Vol.19(2):91-95 Zhou, Z. A., Z. Xu, J. A. Finch, H. Hu and S. R. Rao. 1997. Role of hydrodynamic cavitation in fine particle flotation. Int. J. Minter. Process. Vol.51:139-149. Zhou, L. F., Q. Zhang. 2005. Study on the effect of fine particle flotation when the bubble size changes. Nonferrous Metals (Mineral Processing). Vol.3:21-23 丸山英男，關秀司，鈴木翼，酒井信。1992。Clarification of organic solid suspension by bubble column。北海道大學水產彙報 Vol.43(4):177。張靜文、鍾弘、黃金鳳、蘇慧貞。1997。養豬場作業環境暴露危害研究。勞工安全衛生研究季刊 5(3)：1∼22。陳厚基。1997。畜舍之粉塵及防止惡臭技術之開發及其展望。農牧旬刊Vol.95(12):132-135. 洪佳惠。2002。膽固醇與膽鹽對微脂粒穩定度的影響。國立中央大學。化學工程與材料工程研究所。碩士論文。
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/40390	-
dc.description.abstract	本研究裝置由微細氣泡產生裝置及簡易式氣泡柱組成，並於柱內清水中添加適當濃度之木酢液，測試裝置對畜舍粉塵去除之可能性。由氣泡粒徑最小化實驗結果顯示，添加木酢液添加濃度為2% 時，可縮減氣泡粒徑80%；其餘包括裝置型號、單孔面積、開孔數目、孔口位置、架設角度等5個設計因子之主效應及交互作用，對縮小氣泡粒徑範圍皆僅於20% ~40%。而在氣泡擴散能力部分，則以架設角度與是否添加木酢液影響最顯著，影響程度分別為76.1% 以及70.2%。再以不同木酢添加濃度(2%、1%、0.8%、0.5%、0.2%、0.1% )對造成的氣泡粒徑加以測試，結果顯示，木酢液添加濃度於0.1% ~0.5% 間、pH値控制於6.39~4.55間，可得氣泡粒徑最小化的最佳結果。而由裝置測試實驗結果得知，氣泡柱內液體溫度無分層現象，且為系統中影響最大的因子，因此分別於不同液溫 (25℃、30℃、35℃、40℃、45℃)下，通入3.2 g粉塵測試裝置除塵能力。結果顯示，通入粉塵後，系統會因液內小粉塵量多寡而分成前後兩期，前期浮除能力可用液體溫度進行預測，分別於30℃及42.5℃時達最高跟最低浮除效率；而後期浮除能力可用前期浮除後液中殘留粉塵百分比加以預測，且浮除能力只有前期之2% ~8%。而在浮除能力的表示方面，以浮除效率(mg/s)優於濃縮倍數(1/min)，推測是因部分粉塵溶於液中，導致濃縮倍數被低估所致。	zh_TW
dc.description.abstract	This research is applying the simple microbubble generated device and bubble column system, join proper Pyroligneous acid to dust Control in Livestock Buildings. According to the result of minimizing bubble size，adding Pyroligneous acid can influences bubble size more than 80%,but the coverage of the other factors(the type of the device、Area of air vent、Ａir vent number、Ａir vent location、Ａngle of the device)and it’s interaction are just about 20%~40% .In addition, Ａngle of the device and adding Pyroligneous acid can also influence 76.1% and 70.2% spreading ability of bubbles. And then add 2%、1%、0.8%、0.5%、0.2%、0.1% of Pyroligneous acid to water. Test and show, concentration between 0.1%~0.5%、pH between 6.39~4.55 can reach its top performance. According to the result of device testing, liquid temperature has a equivalent distribution in the bubble column, and it is the most important factor of the system. Therefore, add 3.2g dust when system reach 25℃、30℃、35℃、40℃、45℃. Results show that the system has two stages reactions in accordance with tiny dust concentration. In the preceding stage, ability of flotation can be estimated by liquid temperature, and reach its top and bottom when 30℃ and 42.5℃ separately. On the other hand, the later stage’s ability of flotation can be estimated by the tiny dust concentration at the end of the first stage, and the flotation ability is only 2%~8% of the preceding stage. The results also show that flotation efficiency (mg/s) can estimate flotation ability more precisely than multiple of condensation (1/min). Conjecturing that is because part of dust dissolved in the liquid and underestimated the multiple of condensation.	en
dc.description.provenance	Made available in DSpace on 2021-06-14T16:46:25Z (GMT). No. of bitstreams: 1 ntu-97-R95622017-1.pdf: 5539357 bytes, checksum: c8369108529284acfc2f6b7a51de82ee (MD5) Previous issue date: 2008	en
dc.description.tableofcontents	學位口試委員會審定書....................................i 誌謝....................................................ii 中文摘要................................................iii 英文摘要................................................iv 目錄....................................................vi 圖目錄..................................................ix 表目錄..................................................xi 第一章前言............................................1 1.1 研究背景及動機.................................1 1.2 研究目的.......................................2 第二章文獻探討 ......................................4 2.1 泡沫浮除.......................................4 2.1.1泡沫浮除原理......................................4 2.1.2微細氣泡對浮除之幫助..............................5 2.2 微細氣泡產生裝置設計原理.......................7 2.3 氣泡大小計量法.................................9 2.3.1儀器測定法........................................9 2.3.2公式計算法........................................10 2.4 界面活性劑對氣泡粒徑及泡沫層穩定度之影響.......11 2.5 畜舍粉塵研究...................................14 2.5.1畜舍內粉塵來源及影響因子...........................14 2.5.2畜舍中粉塵顆粒對人畜之影響.........................15 2.6 畜舍除塵法研究及困境...........................17 第三章材料與方法.....................................19 3.1 試驗流程.......................................19 3.2 氣泡粒徑最小化試驗.............................21 3.2.1 微細氣泡裝置最佳化試驗............................21 3.2.1.1 實驗設備及材料 .............................21 3.2.1.2 試驗方法....................................24 3.2.2 木酢液濃度對氣泡粒徑影響試驗......................26 3.2.2.1 實驗設備及材料.............................26 3.2.2.2 試驗方法...................................27 3.2.3 高速攝影資料處理法................................29 3.3 除塵裝置測試...................................31 3.3.1 實驗設備及材料....................................31 3.3.2 試驗方法..........................................33 第四章結果與討論...................................35 4.1 氣泡最小化之結果與討論.........................35 4.1.1 微細氣泡產生裝置最佳化............................35 4.1.2 木酢液對氣泡粒徑之影響............................41 4.1.3 第一階段統整......................................48 4.2 除塵裝置測試結果與討論.........................49 4.2.1氣泡柱內各水質參數隨操作時間之變化分析.............49 4.2.2去除效率隨溶液溫度之變化...........................54 第五章結論與建議......................................62 5.1 結論...........................................62 5.2 建議...............................................64 參考文獻................................................66 附錄A 粉塵控制技術文獻比較表...........................71 附錄B 微細氣泡裝置最佳化試驗資料-微細氣泡放大影像-.....74 附錄C 微細氣泡裝置最佳化試驗資料-模式分析詳細流程-.....87 附錄D 木酢液對氣泡粒徑之影響討論-微細氣泡放大影像-.....93 附錄E 木酢液對氣泡粒徑之影響討論-木酢液成分表-.........96 附錄F 木酢液對氣泡粒徑之影響討論 -氣泡粒徑對溶液pH値迴歸繪製流程-................101 附錄G 去除效率隨溶液溫度之變化-泡沫層狀態與浮除狀態-...104
dc.language.iso	zh-TW
dc.subject	微細氣泡柱	zh_TW
dc.subject	粉塵去除	zh_TW
dc.subject	畜舍	zh_TW
dc.subject	木酢液	zh_TW
dc.subject	泡沫浮除	zh_TW
dc.subject	pyroligneous acid	en
dc.subject	froth flotation	en
dc.subject	livestock building	en
dc.subject	dust remove	en
dc.subject	microbubble column	en
dc.title	簡易式微細氣泡柱運用於畜舍空氣除塵之可行性研究	zh_TW
dc.title	The Study of Applying the Microbubble Column System for Dust Removal Control in Livestock Buildings	en
dc.type	Thesis
dc.date.schoolyear	96-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	姜延年,喻新,謝正義
dc.subject.keyword	微細氣泡柱,泡沫浮除,木酢液,畜舍,粉塵去除,	zh_TW
dc.subject.keyword	microbubble column,froth flotation,pyroligneous acid,livestock building,dust remove,	en
dc.relation.page	106
dc.rights.note	有償授權
dc.date.accepted	2008-07-31
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	生物環境系統工程學研究所	zh_TW
顯示於系所單位：	生物環境系統工程學系

文件中的檔案：

檔案	大小	格式
ntu-97-1.pdf 未授權公開取用	5.41 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。