長與有限圓柱的Magnus效應之近地影響：實驗與計算

Hsin-Hua Lee; 李昕樺

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/68080

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	朱錦洲
dc.contributor.author	Hsin-Hua Lee	en
dc.contributor.author	李昕樺	zh_TW
dc.date.accessioned	2021-06-17T02:12:18Z	-
dc.date.available	2021-01-04
dc.date.copyright	2018-01-04
dc.date.issued	2017
dc.date.submitted	2017-12-28
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/68080	-
dc.description.abstract	Magnus 效應在過去已經被許多學者探討過且已有廣泛的應用，無論是在工程碩球類運動中。然而，近年來近地效應與 Magnus 效應的耦合結果又再次引起研究學者的注意。不過，過去的討論多半著重於靜態的系統–受測物與地面沒有垂直方向的相對速度;因此，此研究將針對主動旋轉且動態接近地面中的圓柱與其周遭流場的變化，並將之與靜態結果比較。在本研究中將比較在二維以及三維流場中動態以及靜態結果。在研究中探討轉動圓柱幾個重要的無因次參數，分別為圓柱切線方向速度與入流速度比值 α、圓柱下降速度與入流速度比值 β 以及地面與移動圓柱間距 SG。所探討的α範圍為0至±0.2和SG 則介於5D到0.5D，D為2cm以及3cm轉動圓柱直徑。根據圓柱轉動方向分為三種:一是當圓柱為無轉動(α = 0);另一則是圓柱為逆時針轉動(α > 0);最後則圓柱以順時針轉動(α < 0)。研究的結果顯示，根據不同的轉動方向流場有著顯著的差異。第一種，在無轉動條件下，受地面影響造成其尾流寬度減小，其升、阻力增加。第二種，在正轉條件下，當 SG 減少，其升、阻力會減少，且其渦旋剝離頻率亦增加。其渦旋會受到地面影響而削弱，因而渦旋剝離位置受入流以及下降速度影響導致尾流向圓柱下方較低位置發展。第三，在逆轉條件下，當 SG 減少，其升力與渦旋剝離頻率減少，阻力則增加。其渦旋會受到地面影響而增強，因而下降時渦旋剝離位置不同造成接近地面後尾流結構不同。且嘗試以穩定性分析正轉、逆轉以及無轉動條件下在接近地面時穩定情形。然而，根據結果不論是靜態或動態，所造成流場的變化是一致的，但是作下降運動對於受力的改變較定點少。	zh_TW
dc.description.abstract	Though Magnus effect and its application had been widely investigated by many scientist and researchers, its behavior under the influence of the near ground effect has recently acquired much attention. However, most studies considered the ground effect as a static surface without relative velocity towards the subject. Therefore, this research is aimed to numerically and experimentally investigate the flow interaction around a rolling cylinder that shifts towards a flat surface in a uniform flow. Further, the results in the dy- namic case were compared to the static cases under both 2 dimensional and 3 dimensional aspects. Some important normalized parameters of the rolling cylinder being discussed through- out the entire investigation are the rotation ratio α, declining velocity ratio β, and the spac- ing gap between the cylinder and the flat surface SG. The range of interest for α is from 0 to ±0.2, and SG from 5D to 0.5D, where D is the diameter of the rolling cylinder chosen to be 2 cm and 3 cm. Note that three types of classification are distinguished according to the rotation motion of the cylinder: One is when the cylinder has non-rotation (α = 0); another would be the cylinder rotating in counterclockwise direction (α > 0); and the other is the clockwise rotation (α < 0) of the cylinder. The results show that the flow pattern significantly varies in each of the three distin- guished types of rotation motion. In the first case, when the cylinder is non-rotation, the ground effect mitigates eddies behind the subject and leads to a higher lift and drag. In the second case, when the cylinder is counterclockwise-rotation, as SG is decreasing, the lift and drag drops, and the separation frequency increases. The vortex around the cylinder is alleviated by the ground effect, and the separation occurs at a lower portion behind the cylinder due to the effect of the incoming flow and declining motion. In the last case, when the cylinder is clockwise-rotation, As SG decreases, the lift and the separation frequency decreases, and the drag increases. The vortex is strengthened by the ground effect, and the separation occurs at a higher portion with the same reasoning. Further, the stability analysis is applied to the three distinguished motions to check for their stability. As a result, the phenomenon of the flow patterns are consistent in both static and dynamics cases, but the force exerted on the cylinder is smaller for the dynamic case.	en
dc.description.provenance	Made available in DSpace on 2021-06-17T02:12:18Z (GMT). No. of bitstreams: 1 ntu-106-R04543034-1.pdf: 82262140 bytes, checksum: f2f4a36d450cb1402bad3ffbefc9dec6 (MD5) Previous issue date: 2017	en
dc.description.tableofcontents	口試委員會審定書................ .................. i 誌謝........................ .................. ii 中文摘要....................................... iii Abstract........................................ iv 目錄.......................................... vi 圖目錄 ........................................ ix 表目錄 ........................................ xii 第一章緒論.................................... 1 1.1 研究背景與動機.............................. 1 1.2 Magnus效應相關文獻........................... 2 1.2.1 不同幾何形狀相關文獻...................... 2 1.2.2 低雷諾數下圓柱相關文獻 .................... 3 1.2.3 高雷諾數下圓柱相關文獻 .................... 7 1.2.4 Magnus效應文獻總結....................... 8 1.3 近地效應相關文獻............................. 9 1.3.1 無轉動圓柱相關文獻 ....................... 9 1.3.2 轉動圓柱相關文獻 ........................ 11 1.3.3 近地效應文獻總結 ........................ 14 1.4 研究目的.................................. 15 1.5 全文架構.................................. 15 第二章基礎理論.................................. 16 2.1 Magnus效應................................ 16 2.2 渦旋剝離.................................. 21 2.3 參數介紹.................................. 22 2.3.1 圓柱參數.............................. 22 2.3.2 無因次參數 ............................ 23 第三章實驗方法.................................. 26 3.1 實驗設備.................................. 26 3.1.1 水平式循環水洞.......................... 26 3.1.2 控制系統.............................. 27 3.1.2.1 下降系統 ........................ 27 3.1.2.2 轉動系統 ........................ 28 3.1.2.3 移動地面系統...................... 28 3.1.3 實驗材料.............................. 30 3.1.4 攝影及顯影設備.......................... 30 3.1.4.1 影像擷取設備...................... 30 3.1.4.2 顯影設備 ........................ 30 3.1.5 實驗架設與流程.......................... 31 3.2 流場顯影及影像分析方法......................... 32 3.2.1 雷射光頁顯影法.......................... 32 3.2.2 粒子影像測速法.......................... 33 第四章數值方法.................................. 34 4.1 網格建構.................................. 34 4.1.1 網格類型.............................. 34 4.1.2 網格設定.............................. 34 4.1.3 邊界條件.............................. 36 4.2 控制方程式................................. 36 4.3 數值方法.................................. 37 4.3.1 分離求解器 ............................ 37 4.3.2 空間離散.............................. 38 4.3.3 時間離散.............................. 43 4.3.4 壓力-速度耦合關係 ....................... 45 第五章結果與討論 ................................ 51 5.1 簡介..................................... 51 5.2 二維定點分析 ............................... 52 5.2.1 流場現象.............................. 52 5.2.2 間距比影響 ............................ 56 5.2.3 轉速比影響 ............................ 59 5.2.4 穩定性分析 ............................ 61 5.2.5 定點分析討論........................... 63 5.3 二維下降分析 ............................... 65 5.3.1 流場顯影.............................. 65 5.3.2 轉速比影響 ............................ 70 5.3.3 下降速度比影響.......................... 73 5.3.4 下降分析討論........................... 74 5.4 三維結果.................................. 76 5.4.1 流場顯影.............................. 76 5.4.2 受力分析.............................. 83 5.5 定點與下降結果比較 ........................... 84 5.6 二維與三維結果比較 ........................... 87 第六章結論與未來展望.............................. 89 6.1 結論..................................... 89 6.2 未來展望.................................. 90 參考文獻....................................... 91
dc.language.iso	zh-TW
dc.subject	渦旋剝離	zh_TW
dc.subject	層流	zh_TW
dc.subject	低雷諾數水洞	zh_TW
dc.subject	Magnus 效應	zh_TW
dc.subject	近地效應	zh_TW
dc.subject	ground effect	en
dc.subject	Magnus effect	en
dc.subject	vortex shedding	en
dc.subject	laminar flow	en
dc.subject	low Re water tunnel	en
dc.title	長與有限圓柱的Magnus效應之近地影響：實驗與計算	zh_TW
dc.title	On the Magnus effect of a (finite) circular cylinder near a ground plate : experiments and computations	en
dc.type	Thesis
dc.date.schoolyear	106-1
dc.description.degree	碩士
dc.contributor.coadvisor	張建成
dc.contributor.oralexamcommittee	楊瑞珍(Ruey-Jen Yang),潘從輝(Tsorng-Whay Pan),林慶龍(Lin, Ching-long)
dc.subject.keyword	Magnus 效應,近地效應,渦旋剝離,層流,低雷諾數水洞,	zh_TW
dc.subject.keyword	Magnus effect,ground effect,vortex shedding,laminar flow,low Re water tunnel,	en
dc.relation.page	97
dc.identifier.doi	10.6342/NTU201704502
dc.rights.note	有償授權
dc.date.accepted	2017-12-28
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	應用力學研究所	zh_TW
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