散熱器下水管 的英文怎麼說

中文拼音 [sǎnxiàshuǐguǎn]
散熱器下水管 英文
hose radiator lower
  • : 散動詞1. (由聚集而分離) break up; disperse 2. (散布) distribute; disseminate; give out 3. (排除) dispel; let out
  • : 名詞1. (器具) implement; utensil; ware 2. (器官) organ 3. (度量; 才能) capacity; talent 4. (姓氏) a surname
  • : 下動詞1. (用在動詞后,表示由高處到低處) 2. (用在動詞后, 表示有空間, 能容納) 3. (用在動詞后, 表示動作的完成或結果)
  • : 名詞1 (由兩個氫原子和一個氧原子結合而成的液體) water 2 (河流) river 3 (指江、河、湖、海、洋...
  • : Ⅰ名詞1 (管子) pipe; tube 2 (吹奏的樂器) wind musical instrument 3 (形狀似管的電器件) valve;...
  • 散熱器 : radiator; radiation; cooler; heat sink
  • 散熱 : heat radiation; radiating; thermolysis; abstract heat; heat dissipation; cooling散熱風門 throttle...
  • 水管 : waterpipe; water carrier; aqueduct; water conduit; water pipe; syphon; siphon (消防) 水管車 hos...
  1. On the above basis, the controlling methods suitable to all types of indoor heating systems for outdoor heating hydraulic system are discussed, and a guide principle of the designing for indoor heating system and outdoor heating hydraulic system is provided

    著重研究了室內採暖系統在安裝恆溫閥后,其運行工況性能參數的變化,在此基礎上,研究了與各種室內採暖系統相適應的室外供系統變量運行策略,闡述了與我國住宅建築採暖計量收費所適應的室內採暖系統和室外供系統的設計原則。
  2. This paper ’ s background is society need, and assimilates experience of former scholar to improve on a liquid self - circulating radiator for electronic component and develops a new form of more effective compound heat pipe radiator for electron component. at the same time, which is charged respectively by four natural working substance ? ? methanol, ethanol, acetone, water and a refrigeration ? ? r123

    本文正是在這樣一個社會需求背景,吸取前人工作經驗,改進原有電子件液體自循環冷卻系統,並開發出一種更為有效的電子件復合型裝置,分別使用了四種天然工質? ?甲醇、乙醇、丙酮、和一種製冷劑? ? r123進行試驗。
  3. The condensation heat - exchange characteristic of a separate - type heat - pipe was studied on a 1 : 1 model. the heat pipe is heated by electricity, and working fluid is distilled water, and it is cooled by air. the experimental results show that, ( 1 ) when charging liquid ratio is 45 %, condensation heat - exchange coefficient reaches to maxium ; ( 2 ) when there is not non - condensing gas, the coeffcient decreases a little with the increase of vapour pressure, and it decreases by 9. 5 % when the pressure increases from 0. 16mpa to 0. 36mpa ; ( 3 ) when there is non - condensing gas, the coefficient decreases a little, but when the gas is discharged by an exhaust value, it can be improved, when the volume content of the gas is 2. 5 %, it can increased by 22 % ; ( 4 ) the effect of the non - condensing gas on the coefficient decreases with the increase of the pressure, and when the volume content of the gas is 5 % and the pressure increases from 0. 16mpa to 0. 36mpa, the coefficient increases by 6 %. the relative curves are given between condensation heat - exchange coefficient and air flowrate, charging liquid ratio and vapour pressure

    建立了空氣冷卻實驗臺,的加方式為電加,工質為蒸餾.在1 1模型上對分離式內凝結換特性、不凝性氣體對凝結換的影響及不凝性氣體的擴規律進行了試驗,得出分離式有一最佳充液率,其值為45 %左右;凝結換系數隨著蒸汽壓力的增加略有降低,在實驗的壓力范圍內,降低了9 . 5 % ;不凝性氣體對分離式的凝結換僅影響冷凝段部較小部分,通過排氣閥排出不凝性氣體可有效地改善冷凝段部的凝結換;隨著壓力的增加,不凝性氣體對分離式冷凝段的影響減少.這些結論可用於分離式的工程設計和控制
  4. Abstract : the condensation heat - exchange characteristic of a separate - type heat - pipe was studied on a 1 : 1 model. the heat pipe is heated by electricity, and working fluid is distilled water, and it is cooled by air. the experimental results show that, ( 1 ) when charging liquid ratio is 45 %, condensation heat - exchange coefficient reaches to maxium ; ( 2 ) when there is not non - condensing gas, the coeffcient decreases a little with the increase of vapour pressure, and it decreases by 9. 5 % when the pressure increases from 0. 16mpa to 0. 36mpa ; ( 3 ) when there is non - condensing gas, the coefficient decreases a little, but when the gas is discharged by an exhaust value, it can be improved, when the volume content of the gas is 2. 5 %, it can increased by 22 % ; ( 4 ) the effect of the non - condensing gas on the coefficient decreases with the increase of the pressure, and when the volume content of the gas is 5 % and the pressure increases from 0. 16mpa to 0. 36mpa, the coefficient increases by 6 %. the relative curves are given between condensation heat - exchange coefficient and air flowrate, charging liquid ratio and vapour pressure

    文摘:建立了空氣冷卻實驗臺,的加方式為電加,工質為蒸餾.在1 1模型上對分離式內凝結換特性、不凝性氣體對凝結換的影響及不凝性氣體的擴規律進行了試驗,得出分離式有一最佳充液率,其值為45 %左右;凝結換系數隨著蒸汽壓力的增加略有降低,在實驗的壓力范圍內,降低了9 . 5 % ;不凝性氣體對分離式的凝結換僅影響冷凝段部較小部分,通過排氣閥排出不凝性氣體可有效地改善冷凝段部的凝結換;隨著壓力的增加,不凝性氣體對分離式冷凝段的影響減少.這些結論可用於分離式的工程設計和控制
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