Pool的問題，透過圖書和論文來找解法和答案更準確安心。 我們找到下列包括價格和評價等資訊懶人包

The Last Pool of Darkness

為了解決Pool的問題，作者Robinson, Tim 這樣論述：

Tim Robinson (1935-2020) was the author of The Last Pool of Darkness and Listening to the Wind. A cartographer and writer, he also studied mathematics at Cambridge and worked for many years as a teacher and visual artist in Istanbul, Vienna, and London, among other places. In 1972 he moved to the Ar

an Islands. In 1986 his first book, Stones of Aran: Pilgrimage, was published to great acclaim. The second volume of Stones of Aran, subtitled Labyrinth, appeared in 1995. He also published collections of essays and maps of the Aran Islands, the Burren, and Connemara. Connemara: Listening to the Win

d, first published in 2006, won the Irish Book Award for Nonfiction.

Pool進入發燒排行的影片

超疏水性在結露狀況下對氣冷式熱交換器性能的影響

為了解決Pool的問題，作者莫尼實 這樣論述：

濕空氣冷凝是熱管理系統中常見的過程，在冷凍空調循環中尤為重要，冷凝現象發生於當熱交換器，特別是蒸發器，在低於空氣露點的溫度下操作時。此現象將會導致鰭片側的冷凝液滴(膜)滯留(retention)與橋接(bridging),進而造成風機壓降與能耗的增加。本研究旨在開發一種超疏水熱交換器，通過其疏水特性，最大限度地減少冷凝水的滯留和橋接。本研究提出一種新型的超疏水性鰭片換熱器設計構想，採用傾斜鰭片排列以達到最小壓降和最大節能效果。本研究從熱傳與壓降性能的觀點切入，將新型超疏水性傾斜鰭片換熱器與其他換熱器作比較分析，分別為：超疏水水平鰭片換熱器、親水性傾斜鰭片換熱器、與親水性水平鰭片換熱器。此外，

本研究藉由改變不同的操作條件，如：進氣溫度、相對濕度和鰭片間距，對這四種換熱器進行性能測試。親水和超疏水換熱器中分別以膜狀冷凝和滴狀冷凝模式為主。由於其表面的高潤濕性，親水換熱器會有較大的液滴脫落直徑。相比之下，超疏水換熱器中發生的 Cassie-Baxter 液滴模式，促使了較小的液滴脫落直徑。本研究建立了一個力平衡模型來分析液滴脫落直徑，模型參數包括了表面張力、慣性力與重力對液滴的影響。本研究基於韋伯數(We)與邦德數(Bo)與液滴脫落直徑，引入了一個新的無因次參數( )，該無因次參數 可預測表面的凝結水脫落能力，在給定的鰭片間距下， 越小代表凝結水脫落能力越好。研究結果表明，滴狀冷凝的

超疏水換熱器在濕空氣下的冷凝熱傳性能相較膜狀冷凝的親水性換熱器並未有顯著的提升，此結果可歸因於非凝結性氣體效應。然而，在壓降方面，超疏水性換熱器與親水性換熱器相比，可帶來高達70%的壓降降低，大幅提升節能效果。壓降的降低歸因於聚結誘發的液滴跳躍現象，使得冷凝水連續脫落。

Rebel, Brave and Brutal (Winter, White and Wicked #2)

為了解決Pool的問題，作者Dittemore, Shannon 這樣論述：

The gripping sequel to Winter, White and Wicked that boasts the thrills of Mad Max: Fury Road and the icy magic of Frozen Sylvi Quine, the best rig driver on Layce, has braved the dangers of the Shiv Road to save her friend and learned the truth of her power over Winter. Now, she’s joined the rebel

s working to take down the Majority. Her magic could change the course of their fight, and she agrees to meet the king of Paradyia to offer an exchange: the healing powers of the Pool of Begynd for his army. The journey won’t be easy. To get there, Sylvi will have to navigate the Kol Sea, crossing

through Winter’s storms and swarms of her Abaki--all while outrunning the Majority, who have sent their best Kol Master to track her down and bring her in, dead or alive. But she isn’t traveling alone. Mars Dresden knows Sylvi is the key to freeing Layce, and demands she train like it. Kyn, the boy

with stone flesh and a soft heart, is bound to Sylvi in more ways than one, a connection that both hurts and heals. And Lenore, Sylvi’s best friend, insists the Majority pay for what they’ve done to her parents. Even though her crew believes in her, Sylvi’s still learning to use her power, and Wint

er’s whispers are constant . . . Will she be able to control Winter when it matters most? Or will this be the end of the rebellion? Shannon Dittemore is an author, speaker, and contributor to the blog Go Teen Writers, which was one of Writer’s Digest 101 Best Websites for Writers. When she’s not

at her desk, she can be found in the wilds of Northern California, adventuring with her husband, their two children, and a husky named Leonidas.

結合Breath Figure 週期性液滴透鏡之奈米雷射直寫加工技術

為了解決Pool的問題，作者黃彬勝 這樣論述：

　本研究為利用液滴透鏡輔助奈秒雷射於矽基板上加工奈米結構。開發的技術重點是利用Breath Figure法生成的高分子薄膜微孔模板，並在此模板上浸潤甘油來形成微米尺度之液態透鏡陣列，做為雷射二次聚焦之透鏡，再結合雷射熔融基板材料形成微奈米結構的製造技術。　　在Breath Figure製作上，將Polystyrene、Polymethylmethacrylate與甲苯混合成高分子溶液，透過甲苯高揮發特性以帶走基板表面熱能，使環境中水分子冷凝於基板表面，待溶液蒸發完畢形成高分子微孔薄膜。本論文使用Dip Coating方式測試兩種拉升速度，900 mm/min與400 mm/min，以製作所需

之微孔薄膜。其所形成之微孔孔徑在拉升速度900 mm/min時介於 1.2 μm 至 3.8 μm之間，400 mm/min則是介於1 μm 至3.6 μm之間，而孔洞剖面為橢圓狀，在拉升速度900與400 mm/min膜厚分別為1.5、1.2 μm。　　接著於微孔孔洞內浸潤甘油形成甘油透鏡，將雷射光經由甘油透鏡二次聚焦達到熔融矽基板。在本研究中探討不同雷射功率與不同掃描間距對於所加工出結構之影響。其結果顯示在雷射以掃描間距20 μm、正離焦4.8 mm、雷射功率密度介於1.63×107~1.74×107 W/cm2能加工出矽微奈米結構，經由量測得知微峰結構直徑介於1.1~1.4 μm之間。在

拉升速度400 mm/min所加工出來的結構高度介於20~160 nm，而在拉升速度900 mm/min結構高度介於20~130 nm。