船用消音器之聲學性能與背壓分析

劉信賢; Hsin-Hsien Liu

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/98106

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	王昭男	zh_TW
dc.contributor.advisor	Chao-Nan Wang	en
dc.contributor.author	劉信賢	zh_TW
dc.contributor.author	Hsin-Hsien Liu	en
dc.date.accessioned	2025-07-25T16:06:04Z	-
dc.date.available	2025-07-26	-
dc.date.copyright	2025-07-25	-
dc.date.issued	2025	-
dc.date.submitted	2025-07-17	-
dc.identifier.citation	M. E. Delany, & E. N. Bazley, “Acoustical properties of fibrous absorbent materials.”, Applied acoustics, 3(2), 105-116, 1970. Y. Miki, “Acoustical properties of porous materials-Modifications of Delany-Bazley models.” , Journal of the Acoustical Society of Japan (E), 11(1), 19-24, 1990. D. L. Johnson, & J. Koplik, & R. Dashen, “Theory of dynamic permeability and tortuosity in fluid-saturated porous media.”, Journal of fluid mechanics, 176, 379-402, 1987. Y. Champoux, & J. F. Allard, “Dynamic tortuosity and bulk modulus in air‐saturated porous media.”, Journal of applied physics, 70(4), 1975-1979, 1991. N. Voronina, “Acoustics Properties of Fibrous Materials”, Applied Acoustics, 42, 165-174, 1994. N. Voronina, “An Empirical Model for Rigid Frame Porous Materials with High Porosity”, Applied Acoustics, 51, 181-198, 1997. C. N. Wang, “Numerical Decoupling Analysis of a Resonator with Absorbent Material”, Applied Acoustics, 58, 109-122, 1999. C. N. Wang, & C. H. Wu, & D. T. Wu, “A Network Approach for Analysis of Silencers with/without Absorbent Material”, Applied Acoustics, 70, 208-214, 2009. L. S. Peat, “The transfer matrix of a uniform duct with a linear temperature gradient”, Journal of Sound and Vibration, 123, 43-53, 1988. Y. H. Kim, & J. W. Choi, & B. D. Lim, “Acoustic characteristics of an expansion chamber with constant mass flow and steady temperature gradient (theory and numerical simulation)”, ASME, Journal of Vibration and Acoustics, 112, 460-467, 1990. C. N. Wang, & Y. N. Chen, & J. Y. Tsai, “The application of boundary element evaluation on a silencer in the presence of a linear temperature gradient”, Applied Acoustics, 62, 707-716, 2001. F. E. Marble & S. M. Candel, “Acoustic Attenuation in Fans and Ducts by Vaporization of Liquid Droplets.” AIAA Journal, 634-639,1975. PK. Mahanta, & S. Vajpayee, & MM. Sadek, “Suspended Water Droplets as a Means of Noise Reduction”, Applied Acoustics, 77-90,1986. L. J. Eriksson, "Higher order mode effects in circular ducts and expansion chambers", The Journal of the Acoustical Society of America, 68, 545-550,1980. 王昭男，邊界元素法在汽機車消音器性能分析之應用，國立臺灣大學造船及海洋工程學研究所博士論文，1993。 M. Stewart, “Surface Production Operations: Volume III: Facility Piping and Pipeline Systems.”, Gulf Professional Publishing, 2015. Crane Co., “Flow of Fluids through Valves, Fittings, and Pipe.”, Metric ed.-SI units., Crane Co., 1999. F. M. White, “Fluid Mechanics 4th ed.”, WCB, McGraw-Hill, 1999. 佟峻桓，多孔纖維材質吸音特性之分析研究，國立臺灣大學造船及海洋工程學研究所碩士論文，1999。林迺凱，多腔體消音器之聲學性能設計與分析，國立臺灣大學工程科學及海洋工程學研究所碩士論文，2022。第二代消音器廠商繪製之工程圖，2022。第三代消音器廠商繪製之工程圖，2023。 A. Selament and Z. L. Ji, “Acoustic attenuation performance of circular expansion chambers with extended inlet and outlet”, Journal of Sound and Vibration, 223(2), 197-212, 1999. A.Selameta, & F. D. Deniab, & A.J. Besab, “Acoustic behavior of circular dual-chamber mufflers” Journal of Sound and Vibration, 265, 967–985, 2003. L. E. Kinsler, & A. R. Frey, “Fundamentals of Acoustics,4th Edition.”, John Wiley & Sons, Inc., 2000	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/98106	-
dc.description.abstract	本研究針對大型船艦排氣系統中之消音器，進行聲學性能與背壓特性之綜合分析，並應用有限元素法建立模擬模型以探討其行為。首先，透過背壓理論所建立之經驗公式對第二代消音器進行背壓推估，並與實測數據進行趨勢比對後，進一步透過幾何調整中孔延伸管孔徑與長度，以降低背壓並設計出第三代消音器。背壓分析結果顯示，主要背壓集中於膨脹管與中孔、入出口管之截面積變化處，故尺寸調整策略優先針對延伸管孔徑進行優化。聲學性能方面，本研究亦探討噴灑水霧對消音性能之影響，發現其在高頻區段具有顯著提升傳輸損失之效果。為評估其潛在應用效益，分別針對不同霧化比例、水滴尺寸大小等條件進行模擬分析。模擬結果顯示，第三代消音器在加入水霧後，於80Hz以上頻率範圍內皆可達10dB以上之傳輸損失，雖整體聲學性能略低於第二代設計，然其背壓控制表現更為優異，顯示第三代設計於兼顧聲學性能與流體性能方面更具實用性，適用於對低背壓與多頻段消音需求兼備之船用排氣系統。	zh_TW
dc.description.abstract	This study focuses on the comprehensive analysis of acoustic performance and back pressure characteristics of mufflers used in large marine exhaust systems. A finite element model was developed to investigate the muffler’s behavior under various design and operating conditions. Initially, an empirical equation derived from back pressure theory was applied to estimate the pressure loss of the second-generation muffler. The estimated results were compared with experimental measurements, and based on this comparison, the geometry—specifically the diameter and length of the extended perforated pipe—was optimized to reduce back pressure, leading to the development of a third-generation muffler. Back pressure analysis revealed that the major pressure loss occurred near the abrupt changes in cross-sectional area between the expansion chamber and the perforated pipe, as well as at the inlet and outlet regions. Therefore, geometric optimization was primarily focused on the perforated pipe. In terms of acoustic performance, the study also investigated the effect of water droplets injection, which was found to significantly enhance sound attenuation, particularly in the high-frequency range. To evaluate its practical effectiveness, a series of simulations were conducted considering different scattering ratios, droplet sizes, and the pore diameter derived from measured back pressure. The results indicate that the third-generation muffler, when combined with water mist, achieves more than 10 dB of transmission loss across the frequency range above 80 Hz. Although its overall acoustic performance is slightly lower than that of the second-generation design, the improved back pressure characteristics make it more suitable for practical applications where both low back pressure and wideband noise attenuation are required in marine exhaust systems.	en
dc.description.provenance	Submitted by admin ntu (admin@lib.ntu.edu.tw) on 2025-07-25T16:06:04Z No. of bitstreams: 0	en
dc.description.provenance	Made available in DSpace on 2025-07-25T16:06:04Z (GMT). No. of bitstreams: 0	en
dc.description.tableofcontents	誌謝 I 摘要 II ABSTRACT III 目次 V 圖次 VIII 表次 IX 第一章緒論 1 1.1 研究動機與目的 1 1.2 文獻回顧 2 1.3 論文架構說明 3 第二章理論方析 4 2.1 聲學理論 4 2.1.1 波動方程式 4 2.1.1.1 狀態方程式（State Equation） 4 2.1.1.2 連續方程式（Continuity Equation） 5 2.1.1.3 動量方程式（Momentum Equation） 5 2.1.1.4 波動方程式（Wave Equation） 5 2.1.2 圓管消音器之音壓 6 2.1.3 消音器消音性能之參數 9 2.2 背壓理論 10 2.2.1 柏努力方程式 10 2.2.2 水頭損失經驗公式 11 2.2.2.1 沿程損失（Friction Loss） 11 2.2.2.2 局部損失（Minor Loss） 11 2.2.3 背壓評估模型 15 2.3 吸音材理論 16 2.3.1 Voronina經驗模型 16 2.3.2 流動阻抗與孔徑關係之公式 17 第三章船用消音器背壓分析 18 3.1 幾何模型與分析條件 18 3.2 分析結果 25 3.2.1 第二代消音器模擬與實測背壓值分析 25 3.2.2 第三代消音器調整策略 27 3.2.3 第三代消音器模擬與實測背壓值分析 30 第四章船用消音器聲學性能分析 32 4.1 分析方法與條件設定 32 4.2 消音器結構對消音性能之影響探討 35 4.3 溫度變化對消音性能之影響探討 38 4.4 噴水霧對消音性能之影響探討 40 4.4.1 聲波衰減係數隨頻率變化分析 40 4.4.2 將噴水霧視作添加吸音材分析 42 4.5 不同噴水霧條件對消音性能之影響探討 44 4.5.1 不同霧化比例對消音性能之影響 44 4.5.2 不同水滴大小對消音性能之影響 45 第五章結論 47 參考文獻 48 附錄A 50 附錄B 51 附錄C 52 附錄D 53	-
dc.language.iso	zh_TW	-
dc.subject	有限元素法	zh_TW
dc.subject	消音器設計	zh_TW
dc.subject	吸音材與水霧	zh_TW
dc.subject	背壓分析	zh_TW
dc.subject	Muffler Design	en
dc.subject	Back Pressure Analysis	en
dc.subject	Porous Material and Water Droplets	en
dc.subject	Finite Element Method	en
dc.title	船用消音器之聲學性能與背壓分析	zh_TW
dc.title	Analysis of Back Pressure and Acoustic Performance of Vessel Mufflers	en
dc.type	Thesis	-
dc.date.schoolyear	113-2	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	謝傳璋;宋家驥	zh_TW
dc.contributor.oralexamcommittee	Chuan-Cheung Tse;Chia-Chi Sung	en
dc.subject.keyword	消音器設計,背壓分析,吸音材與水霧,有限元素法,	zh_TW
dc.subject.keyword	Muffler Design,Back Pressure Analysis,Porous Material and Water Droplets,Finite Element Method,	en
dc.relation.page	53	-
dc.identifier.doi	10.6342/NTU202501911	-
dc.rights.note	同意授權(全球公開)	-
dc.date.accepted	2025-07-18	-
dc.contributor.author-college	工學院	-
dc.contributor.author-dept	工程科學及海洋工程學系	-
dc.date.embargo-lift	2025-07-26	-
顯示於系所單位：	工程科學及海洋工程學系

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