200921023 九、發明說明: 【發明所屬之技術領域】 本發明係有關於-種瞬_導環保節能冰風扇,尤指 種藉由-致冷晶片將-水箱急速降溫,透過該水箱所連 接之-送冷模組並藉由-風扇將低溫之冷風排出於殼體 之外,達到迅速將週遭溫度降低之目的。 【先前技術】 、、由於全球的暖化現象,導致隸的異常變化,也同時 造成各地平均氣溫的上升,尤其在漫長的酷暑當中,如何 使大眾消暑降溫、以及快速且大幅降低室内溫度以更迎合 人類居住之環境,為其主要改善之課題。 近年來其製造技術迅速的發展和各種優 料的不斷問世,逐漸成為民用製冷業界的新t而半導體 2不僅以獨具的設備體積小、無機械轉動、溫度易自控 =能魅力在國防、航天、醫療等特殊領域博取了各界的 ^其冷裝置可輯過選擇不_致冷晶片以及 的空間提供最合理賴冷量。料佳的舰,給欲散熱 請參閱圖-,圖一為習用冷風扇之剖面干 一所示,其卜習用冷風扇 :圖圖 扇丨2、-致冷晶片13、一韓片::及-:體丨卜-風 該致冷晶片更包括有冷接:散熱風扇15。 v得面131、以及一熱接面 200921023 132。 該風扇12係設置於該箱體11之上,且於該箱體11 内部之一分隔部111上設置有該致冷晶片13,該分隔部 111係將该箱體11内部大致分隔成一冷卻區112以及一 排熱區113兩區域,該致冷晶片13之該冷接面131係位 於該冷卻區112中,且與該鰭片14相連接,並透過位於 該箱體11正面之該風扇12將該縛片14所散發之冷空氣 抽出該箱體11之内以產生冷風。 該冷接面131相對之另一面,也就是該致冷晶片13 之該熱接面132,係位於該排熱區113中,由於該致冷晶 片13運作時’於該冷接面131降溫的同時,該熱接面132 亦同時散發出熱能於該排熱1丨13之空氣中,_該箱體 η後方所設之該散熱風扇15將該排熱區113 $氣中的熱 能抽出於該箱體11之外。 該習用冷風扇1僅透過該致冷晶片13之該冷接面 131與簡片14相連接,其效率不高,且無法於短時間 内將該溫度降至-定程度,而該熱接面132所產生之故能 更無法透賴雜風们5迅賴出於體u之外,其 殘留於該排麵113之溫度核轉該致冷晶片13之^ 作效能’更卩_彡_該致冷晶片13之該冷接面⑶ 行降溫的速度。 【發明内容】 本發明之第-目的,在於提供—種糊超導環保節能 200921023 水几羽係藉&致冷晶片將—水箱内之液體溫度迅速降 低至預設溫度’轴透職水騎連接之—送冷模組利用 -風扇將低溫冷風導出,達到迅速令周遭環境溫度降低之 目的。 本發明之第二目的,在於提供—種咖超導環保節能 冰風扇,係職—超導物質充填於-料冷管内,使該水 箱之低溫得以迅速藉由該超導物f傳遞於該超導冷管上 之導冷鰭片,達到加速低溫傳導的目的。 本發明之第三目的,在於提供—種瞬間超導環保節能 冰風扇,係運用-超導物質充填於一熱導管内,令其連接 之該致冷晶片所產生的熱能得以迅速界宜該導熱管傳遞 於該散熱則上,達到可快速將熱能藉由散熱風扇排出之 目的。 為達上述之目的’本發明係提供—種瞬間超導環保節 能冰風扇,其包括有:一殼體、一水箱、至少一致冷晶片、 -送冷模組、-風扇、一散熱模組、以及一控制二曰。該 殼體係為-中空殼狀,其更包括:―出風σ、以及一散熱 口。該送賴,蚊包括:複數個超導冷管、紐個導冷讀 片、以及-超導物質。該散熱模組更包括有:―散熱轉片、 至少-熱導管、-超導物質、以及—散熱風扇。 於該水箱内設有-紐’並藉由該致冷晶片將該水箱 内之該液體急速降溫’進而將低溫傳遞於該送冷模組之 上,且利賴風扇透職送冷模祕冷風㈣$風口 於該殼體之外。 200921023 面冷日0片係包括冷接面、以及—熱接面;該冷接 面則狄置於該水箱外側’且附著於該水箱壁之上。該散熱 模組係與該致冷⑼之該熱接面相連接,並與該殼體之^ 散熱口相對應,令無得轉_散細排出於該殼體之 外。該控鮮元雜該風融㈣致冷⑼電 控制其運作。 1 ★該送冷模組之騎導冷管係為_之巾好體,其部 分管體貫穿且伸人該水箱之内。該導冷鰭片係為金^片 狀,於上方設魏數_孔,且藉倾開孔分別以一敢 距離間隔設置於該稱冷管之上。_超導冷管之管體内 充填有-超導物質’係將該水勒透過該致冷晶片所產生 之低溫藉由該超導物質迅速傳遞於該超導冷管,進而將低 溫間接傳遞於該導冷鰭片之上者。 、- 該散熱模組之该熱導管係為一中空封閉之管體,於管 内充填有該超導物質,其-端設置於該致冷晶片之該轨接 面上,另-端職於該散熱鰭片之上。該賴風扇魏置 於°亥政熱鰭片之上’並與該殼體之該散熱口相對應。該散 熱模組之該熱導管係將該致冷晶片所產生之熱能透過該 熱導管傳遞於該散熱鰭片之上,藉由該散熱鰭片上所設置 之該散熱風扇將熱能經由該散熱口排出於該殼體之外者。 【實施方式】 為了能更清楚地描述本發明所提出之瞬間超導環保 節能冰風扇’以下將配合圖示詳細說明之。 200921023 請參晒二,圖二為本發明瞬間超導_節能冰風扇 之立體透視示意圖。如圖二所示,該瞬間超導環保節能冰 風扇2係包括:—殼體21、—水箱22、至少—致冷晶片 23、-送冷模組24、—風扇25、—散熱模組%、以及一 控制單元27。該殼體21係為—中空殼狀,其更包括:一 出風口 2U、以及-散細212。觀冷模組%更包括: 複數個超導冷管24卜複數個導冷鰭片242、以及一超導 物質243 (另示於圖三)。該散熱模組%更包括有:一散 熱續片261、至少·一轨導營in ^ 等5 262 超導物質263 (另示 於圖三)以及一散熱風扇264。 該水箱22為-中空之金屬容器,係位於該殼體21 之内,且於該水箱22内部空間處充填有一液體% (另示 於圖二)。該水箱22之材質,可以是鐵、銅、銘、鋼、不 鏽鋼、銘合金、以及鈦合金其中之一。該液體3〇可以是 水、油、以及冷卻液其中之一。 該致冷晶片23也就是-般業界所稱之半導體溫差致 冷晶片(Thermoelectric Cooling Chip),其具有熱電能量轉 換特性的材料’在通直流電時有製冷功能,因此稱為熱 電致冷’触冷⑼B目前是由碲化轉材料所做成的 半導體θβ片。該致冷晶片23係包括有:一冷接面231、 以及一熱接面232。 s亥致冷晶片23於工作時會發生所謂的㈤爾帖效 應]’即當直流電通過兩種不同導電材料構成的回路時, 結點產生吸減放熱縣’也就是說概冷^ 23通入 200921023 直流電後,該致冷晶片23晶片其中之該熱接面232溫度 升尚並向外界放熱,相對之另一該冷接面231則溫度會降 低,並從外界吸熱產生製冷效果。 該致冷晶片23之該冷接面231係設置於該水箱22 夕曰卜側’且附著於其水箱壁之± ’透過該水箱22將該致冷 晶片23之該冷接自231所產生之低溫傳遞至該水箱22 内之雜體30巾’令該水箱22内之概體3()得以急速 二降至預設溫度。由於紐冷晶片23且係屬市面上可購 得之το件,轉本㈣之重點技術雖,故不贅述其詳細 構成。 二亚配合圖二所示,圖三為本發明瞬間超驾 環保節能冰風扇之A_A舰示_。如圖三所示,該i| 冷模組24之該超導冷管241係為封閉之中空管體,其苟 :e體貝穿且伸入該水箱22之内’於該超導冷管加之 =内充填有該超導物f 243。該超導物質_可以是還 声市售之習用超導熱㈣,但其#作溫度係接近於攝氏 U及疋·低溫為較佳。 門孔^冷則242係為金屬片狀’且於上方設有複數個 242卜且藉由該開孔期 =烟2外部之該超導冷管二:= 藉由該超導_急速降溫的同時, 位於該水箱導_43迅速的由 外部之該超導〜2σ4Γ 1傳遞於該水箱22 令吕241上’並同時將低溫快速傳遞至設置 200921023 於該超導冷管241上之該導冷鯖片242上。該超導冷管 241與該導冷韓片242之材質,可以是鐵、銅、銘、鋼、 不鏽鋼、鋁合金、以及鈦合金其中之一。 該風扇25係設置於該殼體21之内,並位於該送冷模 組24之後方,也就是大致位於該複數個導冷鰭片242後 方’且與該殼體21之該出風口 211大致相對應。於該風 扇25運作時,利用該風扇25產生氣流,且分別透過該送 冷模組24之複數個散熱縛片242中央所間隔之預設距離 D處,經由將該散熱縛片242所散發之低溫帶出成為一冷 風,並由該出風口 211排出於該殼體21之外。 請再參閱圖二所示’該散熱模組26係位於該殼體2ι 之内γ、中該散熱風扇264係設置於該散熱鰭片261 之上,並與該殼體21之該散熱口 212相對應。該熱導管 262係為一中空封閉之管體,於管内充填有一超導物質 263 (如圖二所示),其一端設置於該致冷晶片23之該熱 接面232上,另一端則設於該散熱鰭片261之上,係將該 致冷晶片23之該熱接面232所產生之熱能透過該熱導管 262傳遞於_熱鰭片261之上,藉由該散熱鰭片261上 所。又置之該政熱風扇264將熱能經由該散熱口 212排出於 該殼,21之外。該熱導管加與該散熱縛片261之材質, 可以是鐵、銅、紹、鋼、不細,合金、以及鈦合金其 中之一。該超導物質263可以是選購自市售之習用超導熱 材料。 該控制單元27係與該齡晶# 23、風扇25、以及散 12 200921023 熱模組26之該散熱風扇264做電性連接,並控制該瞬間 超導環保節能冰風扇2進行運作,且姻-獅模組28 係提供該瞬間超導環保節能冰風扇2運作時所需之電 力,可透過該控制單元27操控該風扇25的風速以及該致 冷晶片23之冷卻效率。 以下所述之本發明其他較佳實施例中,因大部份的元 件係相同或類似於前述實施例,故相同之元件與結構以下 將不再贅述,且相同之元件將直接給予相同之名稱及編 號,並對於類似之元件則給予相同名稱但在原編號後另增 加奂文字母以資區別且不予贅述,合先敘明。 凊參閱圖四’圖四為本發明瞬間超導環保節能冰風扇200921023 IX. Description of the invention: [Technical field of the invention] The present invention relates to an instant-conducting environmentally-friendly and energy-saving ice fan, in particular to a rapid cooling of a water tank by a cryogenic wafer, which is connected through the water tank - The cooling module is sent and the low-temperature cold air is discharged outside the casing by the fan to quickly reduce the ambient temperature. [Previous technology] Due to the global warming phenomenon, the abnormal changes of the Lie, and the average temperature rise in various places, especially in the long heat, how to make the public cool down, and quickly and greatly reduce the indoor temperature to more Catering to the environment in which humans live is a major improvement issue. In recent years, the rapid development of its manufacturing technology and the continuous advent of various excellent materials have gradually become the new t in the civil refrigeration industry. The semiconductor 2 is not only unique in its size, but also has no mechanical rotation, and temperature is easy to control. Special fields such as medical treatment have won all kinds of cold equipment. The cold equipment can be selected to provide the most reasonable cooling capacity. For the best ship, please refer to the figure for the heat dissipation. Figure 1 shows the profile of the conventional cold fan. The cold fan is used: Figure 2, Cooling Chip 13, and a Korean film:: -: Body Buffer - Wind The cooling chip further includes a cold junction: a cooling fan 15. v has a face 131, and a hot junction 200921023 132. The fan 12 is disposed on the casing 11 , and the cooling fin 13 is disposed on a partition 111 of the casing 11 , and the partition 111 substantially divides the interior of the casing 11 into a cooling zone. 112 and a row of hot zones 113, the cold junction 131 of the cooled wafer 13 is located in the cooling zone 112, and is connected to the fin 14 and passes through the fan 12 located on the front surface of the casing 11. The cold air emitted from the tab 14 is drawn out of the casing 11 to generate cold air. The opposite side of the cold junction 131, that is, the heat junction 132 of the refrigerant wafer 13, is located in the heat rejection zone 113, and is cooled by the cold junction 131 when the refrigerant wafer 13 is in operation. At the same time, the hot junction 132 also emits thermal energy in the air of the exhaust heat 1丨13, and the heat dissipating fan 15 disposed behind the box n extracts the heat energy in the exhaust heat zone 113$ Outside the cabinet 11. The conventional cold fan 1 is connected to the thin piece 14 only through the cold junction surface 131 of the refrigerating wafer 13, and the efficiency is not high, and the temperature cannot be lowered to a certain extent in a short time, and the hot junction The reason for the generation of 132 can not be more reliant on the winds, and the temperature remaining in the surface of the row 113 is transferred to the cooling chip 13 to be more efficient. The cold junction (3) of the cooled wafer 13 is cooled at a rate. SUMMARY OF THE INVENTION The first object of the present invention is to provide a paste superconducting environmental protection and energy saving 200921023 water plume & refrigeration chip will quickly reduce the liquid temperature in the water tank to a preset temperature 'axis through water ride The connection-cooling module uses a fan to direct the low-temperature cold air to quickly reduce the ambient temperature. The second object of the present invention is to provide a coffee-superconducting environmentally-friendly and energy-saving ice fan, wherein the super-superconducting material is filled in the cold pipe, so that the low temperature of the water tank can be quickly transmitted to the superconductor f. The cold fins on the cold guide tube achieve the purpose of accelerating low temperature conduction. A third object of the present invention is to provide an instant superconducting environmentally-friendly and energy-saving ice fan, which is filled with a superconducting material in a heat pipe, so that the heat generated by the cooled wafer connected thereto can be quickly and uniformly controlled. The tube is transferred to the heat dissipation to achieve the purpose of quickly discharging the heat through the cooling fan. In order to achieve the above purpose, the present invention provides an instant superconducting environmentally-friendly and energy-saving ice fan, which comprises: a casing, a water tank, at least a uniform cold chip, a cooling module, a fan, a heat dissipation module, And a control second. The casing is in the form of a hollow shell, and further includes: an outlet σ and a heat dissipation port. The mosquitoes include: a plurality of superconducting cold tubes, a new cold-guided reading, and a superconducting substance. The heat dissipation module further includes: a heat dissipation fin, at least a heat pipe, a superconducting material, and a cooling fan. Providing a button in the water tank and rapidly cooling the liquid in the water tank by the cooling chip, thereby transmitting a low temperature to the cooling module, and the fan is used to deliver the cold mold cold air. (4) The tuyere is outside the casing. 200921023 The surface of the cold film includes a cold junction and a hot junction; the cold junction is placed on the outside of the tank and attached to the tank wall. The heat dissipation module is connected to the heat junction of the refrigeration (9) and corresponds to the heat dissipation port of the casing, so that no rotation/drain is discharged outside the casing. The control element is mixed with the wind (4) and the cold (9) electricity controls its operation. 1 ★ The cold guide tube of the cold-sending module is a good body of the towel, and a part of the pipe body penetrates and extends into the water tank. The cold fins are in the form of gold sheets, and Wei number_holes are arranged on the upper side, and the tilting holes are respectively arranged on the cold tube at a distance from each other. The superconducting cold tube is filled with a superconducting material, and the low temperature generated by the water passing through the refrigerating wafer is rapidly transmitted to the superconducting cold tube by the superconducting material, thereby indirectly transmitting the low temperature. Above the cold fins. The heat pipe of the heat dissipation module is a hollow closed pipe body filled with the superconducting material, the end of which is disposed on the rail joint surface of the refrigerant chip, and the other end serves Above the heat sink fins. The fan is placed above the Heihui hot fin and corresponds to the heat sink of the housing. The heat pipe of the heat dissipating module transmits thermal energy generated by the refrigerating chip to the heat dissipating fin through the heat pipe, and the heat dissipating fan disposed on the heat dissipating fin discharges heat energy through the heat dissipating port Outside the housing. [Embodiment] In order to more clearly describe the instant superconducting environmentally-friendly and energy-saving ice fan proposed by the present invention, the following will be described in detail with reference to the drawings. 200921023 Please refer to Sun 2, Figure 2 is a perspective view of the instant superconducting _ energy-saving ice fan of the present invention. As shown in FIG. 2, the instant superconducting environmental protection and energy-saving ice fan 2 includes: a casing 21, a water tank 22, at least a cooling chip 23, a cooling module 24, a fan 25, and a heat dissipation module. And a control unit 27. The housing 21 is in the form of a hollow shell, and further includes an air outlet 2U and a fine 212. The cooling module % further includes: a plurality of superconducting cold tubes 24 and a plurality of cold guiding fins 242, and a superconducting substance 243 (shown in Fig. 3). The heat dissipation module % further includes: a heat spreader 261, at least one rail guide in ^ 5 262 superconducting material 263 (also shown in FIG. 3), and a heat dissipation fan 264. The water tank 22 is a hollow metal container which is located inside the casing 21 and is filled with a liquid % at the inner space of the water tank 22 (also shown in Fig. 2). The material of the water tank 22 may be one of iron, copper, iron, steel, stainless steel, alloy, and titanium alloy. The liquid 3 can be one of water, oil, and a cooling liquid. The refrigerant chip 23 is also known as a semiconductor thermo-cooling chip (Thermoelectric Cooling Chip), and the material having thermoelectric energy conversion characteristics has a cooling function when passing through a direct current, so it is called a thermoelectric cooling. (9) B is currently a semiconductor θβ sheet made of a bismuth conversion material. The refrigerating wafer 23 includes a cold junction 231 and a thermal junction 232. When the s-cooled wafer 23 is in operation, a so-called (five) effect occurs.] That is, when the direct current is passed through a circuit composed of two different conductive materials, the node generates a heat-dissipating heat-dissipating county. After the direct current is applied, the temperature of the hot junction 232 of the cooled wafer 23 is raised and released to the outside, and the temperature of the cold junction 231 is lowered, and the heat is absorbed from the outside to generate a cooling effect. The cold junction 231 of the refrigerating wafer 23 is disposed on the side of the water tank 22 and attached to the wall of the water tank 22. The cold junction of the cooling wafer 23 is generated by the water tank 22 from the 231. The low temperature transfer to the miscellaneous body 30 in the water tank 22 causes the main body 3 () in the water tank 22 to be rapidly lowered to a preset temperature. Since the New Cooling Chip 23 is a commercially available το piece, the key technology of this (4) is not mentioned here. In conjunction with Figure 2, Figure 3 shows the A_A ship _ of the instant over-environmental protection and energy-saving ice fan. As shown in FIG. 3, the superconducting cold tube 241 of the i| cold module 24 is a closed hollow tube body, and the e body is worn and protrudes into the water tank 22. The tube plus = filled with the superconductor f 243. The superconducting material _ may be a conventional superconducting heat source (4) which is commercially available, but it is preferable that the temperature is close to Celsius U and 低温. When the door hole is cold, the 242 is a metal sheet shape and a plurality of 242 are provided on the upper side, and the superconducting cold tube 2 is replaced by the opening period = the outside of the smoke 2: = by the superconducting _ rapid cooling At the same time, the water tank guide _43 is quickly transferred from the external superconducting ~2σ4Γ1 to the water tank 22, and the low temperature is quickly transmitted to the cold junction 241 of the 200921023. Bracts 242. The material of the superconducting cold pipe 241 and the cold guide 242 may be one of iron, copper, iron, steel, stainless steel, aluminum alloy, and titanium alloy. The fan 25 is disposed in the casing 21 and located behind the cooling module 24 , that is, substantially behind the plurality of cold-finned fins 242 ′ and substantially corresponding to the air outlet 211 of the casing 21 . Corresponding. When the fan 25 is in operation, the fan 25 generates airflow, and is respectively transmitted through the heat dissipation tab 242 at a predetermined distance D between the centers of the plurality of heat dissipation tabs 242 of the cooling module 24. The low temperature is taken out as a cold air, and is discharged from the casing 21 by the air outlet 211. Referring to FIG. 2 , the heat dissipation module 26 is located in the housing 2 , and the heat dissipation fan 264 is disposed on the heat dissipation fin 261 and the heat dissipation port 212 of the housing 21 . Corresponding. The heat pipe 262 is a hollow closed pipe body filled with a superconducting material 263 (shown in FIG. 2), one end of which is disposed on the heat joint surface 232 of the refrigerant chip 23, and the other end is provided. The thermal energy generated by the thermal junction 232 of the chilled wafer 23 is transmitted through the heat pipe 262 to the heat fin 261, and the heat sink fin 261 is disposed on the heat sink fin 261. . The heat fan 264 is further disposed to discharge heat energy outside the casing 21 via the heat dissipation port 212. The heat pipe is added to the heat dissipating tab 261 and may be one of iron, copper, steel, stainless steel, alloy, and titanium alloy. The superconducting material 263 may be a commercially available conventional superconducting material. The control unit 27 is electrically connected to the cooling fan 264 of the age crystal #23, the fan 25, and the scatter 12 200921023 thermal module 26, and controls the instantaneous superconducting environmental protection and energy-saving ice fan 2 to operate, and The lion module 28 provides the power required for the operation of the instant superconducting environmentally-friendly and energy-saving ice fan 2, and the wind speed of the fan 25 and the cooling efficiency of the chilled wafer 23 can be manipulated through the control unit 27. In the other preferred embodiments of the present invention described below, since the components are the same or similar to the foregoing embodiments, the same components and structures will not be described below, and the same components will be directly given the same names. And number, and the same name is given for similar components, but the original letters are added after the original number to distinguish them and will not be repeated.凊 Refer to Figure 4' Figure 4 is an instant superconducting environmental protection and energy saving ice fan
示一較佳實施例之剖視示_丨…js^娜间 超導環保節能冰風扇之第一較佳實施例與圖二之瞬間超 導環保節能冰風扇不同處在於,該瞬間超導環保節能冰風 扇2a係更包括:-第二水箱22a、至少一第二致冷晶片 2如、以及複數個第二超導冷管241a。該第二水箱22&係 設置於該殼體21a之内,且相對於原該水箱22之上方, 並與複數個第二超導冷管241a相結合。該第二水箱瓜 内部係充填有與該水箱22相同之該液體。 該第二致冷晶片23a係與該控制單元27做電性連 接,其該第二致冷晶片23a之-冷接面23u係設置於該 第二水箱22a外侧,且附著於該第二水箱瓜之水箱= 上,令該第二水箱22a内之該液體3〇得以迅速降溫·而 該第二致冷晶片咖之另-熱接面2办則與該熱導^262 13 200921023 相連接’將該第二致冷晶片23a所產生之熱能傳遞於該散 熱鰭片261之上’並藉由該散熱風扇264將熱能透過該殼 體21a之一散熱口 212a排出於該瞬間超導環保節能冰風 扇2a之外。 於該第二超導冷管241a之管内分別充填有該超導物 質243,其一端係分別貫穿並伸入於該第二水箱22a之 内,且另一端則將原有之該水箱22上方所設之複數個導 冷鰭片242 —併貫穿’且設置於該導冷鰭片242上之該開 孔2421内。也就是說’原有之該超導冷管241與該第二 超導冷管241a係同時貫穿於複數個導冷鰭片242上,且 分別將該水箱22以及該第二水箱22a内之低溫同時傳遞 至該複數個導冷鰭片242之上,使各別之該導冷鰭片242 更能快速的降低溫度,並藉由該風扇25分別透過該導冷 鰭片242之間隔處將該導冷鰭片242所產生之低溫,由該 殼體21a之一出風口 211a以冷風方式帶出於該殼體21a 之外,藉此達到更快速低溫的目的。 該第二水箱22a以及該第二超導冷管241a之材質, 可以疋鐵、銅、銘、鋼、不鏽鋼、鋁合金、以及鈦合金其 中之一。 々請參閱圖五,圖五為本發明瞬間超導環保節能冰風扇 第一較佳實施例之剖視示意圖。如圖五所示,圖五為瞬間 超導%保|卩能冰風扇之第二較佳實施例與圖二之瞬間超 V%保節能冰風扇不同處在於,該瞬間超導環保節能冰風 扇处之該出風口 211b係位於該殼體21b之下方,並與該 200921023 « 2lb n之該送冷模組撕相對應,於該送冷模組24b 後方則設置有該風扇25b,可透過該導冷鰭片242之間隔 處將該冷風導出於該出風口 211b之外。 該水箱22b係設置於該送冷模組2牝之上方,且該送 冷拉組2扑之減導冷冑241其未設置有該導冷鰭片242 之部分係貫穿於該水箱22b之内,係大致為圖二之瞬間超 導%保卽能冰風扇2於該殼體21内之組件呈度倒置 陳設。基於冷空氣下降之原理,可運用該超導物質243 將該水箱22b⑽產生之低溫得以更迅速的傳遞至位於 忒水箱22b下方之該送冷模組24b上’達到加速冷卻效率 者。 此外,於該水箱22b外侧所設置之該致冷晶片2邓, 其該熱接面232將該水箱22b所帶出之熱能,於該殼體 21b内之上方藉由該散熱模組26b排出於該殼體21b之 外更付合熱空氣上歼之原理’同時更加速散熱之效率者。 請參閱圖六,為本發明瞬間超導環保節能冰風扇2c 第二較佳實施例之前視示意圖,其類似於前述各實施例, 也同樣具有包括:殼體21c、内部充填有液體之水箱22c、 一或多個致冷晶片23c、由複數個插入水箱22c内之超導 冷管241c與複數個導冷鰭片242c所構成之送冷模組 24c、用以吹出冷風之風扇25c、控制單元27c、以及電源 模組28c等元件。本第三較佳實施例之瞬間超導環保節能 冰風扇2c與前述各實施例間的不同點在於,瞬間超導環 保節能冰風扇2c的散熱模組26c並不具有散熱鰭片與散 15 200921023 熱風扇。相對地,如圖六所示,瞬間超導環保節能冰風扇 2c的散熱模組26c係由包括一内部裝設有可吸熱液體266 的散熱箱265、以及若干連接於致冷晶片23c之熱接面上 的熱導管262c所構成。該些熱導管262c —端係結合且接 觸於致冷晶片23c之熱接面上,另一端則插置入散熱箱 265内之液體266中。於散熱箱265内之熱導管262c上 更設有複數散熱鰭片267 ’以便使熱導管262c的熱量得 以迅速傳遞並被散熱箱265内之液體266所吸收。於散熱 箱265外也可設置複數散熱鰭片268,用以提供散熱功能 並適當降低散熱箱265内之液體266溫度。對應於該散熱 箱265外之複數散熱鰭片268位置的殼體上並可設置有多 數個透氣孔269,以利空氣流通。藉由此種設計,本發明 之瞬間超導環保節能冰風扇2c在藉由致冷晶片23c、送 冷模組24c與風扇25c來吹送出冷風的同時,致冷晶片 23c之熱接面所產生的熱量將可被散熱箱265内之液體 266所吸收而不需排放至外界。如此一來’瞬間超導環保 節能冰風扇2c將可適於被當作室内機所使用,且可任意 擺置於室内任何位置,也不用擔心致冷晶片23c之熱接面 所產生的熱量會影響冷房效果。當然,於一較佳實施例 中’於控制單元27c中更可增設一溫控單元(圖中未示) 其可監測散熱箱265内之液體266的溫度、以及由風扇 25c所吹送出之冷風的溫度。一旦散熱箱265内之液體266 溫度升高至一預定溫度、或是風扇25c吹送出之冷風低於 另一預定溫度時,控制單元27c將會自動降低或暫停致冷 200921023 晶片2=的操作功率,以達到保護或控溫的效果。 WK上所述’本發明係提供一種瞬間超導環保節能冰風 扇2,其包括有:—殼體2卜—水箱22、至少一致冷晶 1 23、二送冷模組24、一風扇25、一散熱模組%、以及 一控制單元27。該殼體21係為—巾空殼狀,其更包括: =風口 211、以及-散熱口加。該送冷模組%更包括: =個超導冷管241、複數個導冷鰭片242、以及一超導 小一Π綠熱模組%更包括有^散熱鰭片26卜至 262 一超導物質263以及一散熱風扇264。 〜水相22為-中空之金屬容器,係位於該殼體 今致二箱22内部空間處充填有—液體3〇,藉由 ^冷4 23將該水箱22内之該液體3G急速降溫,進 ==遞於該送冷模組24之上,且利用該風扇Μ 將冷風由該出風口扣排出於該殼體 該致冷晶片23係包括··一冷接面231、 面232 ;該冷接面231則設置於^ … 於哕泱铲辟々L 又夏孓孩水耘22外側,且附著 :面^ ί,熱模組%係與該致冷晶片23之該 應,令埶_ 並與該殼體21之該散熱口犯相對 .奴?,、、、此侍以經由該散熱口 212 該控制單元27 = 接,並控制其運作。 /致冷曰曰片23電性連 該送冷模組24之該超導冷管 體,其部分管體貫穿且伸人該41係為封閉之令空管 呷这水相22之内。該導冷鰭片 17 200921023 242係為一金屬片狀,且於上方設有複數個開孔2421,且 藉由該開孔2421分別間隔一預設距離設置於該超導冷管 241之上。於該超導冷管241之管體内充填有該超導物質 243,係將該水箱22内透過該致冷晶片23所產生之低溫 藉由該超導物質243迅速傳遞於該超導冷管241,進而將 低溫間接傳遞於該導冷鰭片242之上者。 該散熱模組26之該熱導管262係為一中空封閉之管 體,於管内充填有該超導物質263,其一端設置於該致冷 晶片23之該熱接面232上,另一端則設於該散熱鰭片261 之上。該散熱風扇264係設置於該散熱鰭片261之上,並 與該殼體21之該散熱口 212相對應。該散熱模組26之該 熱導管262係將該致冷晶片23所產生之熱能透過該熱導 管262帶離該熱接面232,並傳遞於該散熱鰭片261之 上’藉由該散熱鰭片261上所設置之該散熱風扇264將熱 能經由該散熱口 212排出於該殼體21之外者。 唯以上所述之實施例不應用於限制本發明之可應用 範圍’本發明之賴範圍應以本發明之+料概圍内容 所界定技補神及其解變化所含狀粒者。即大 凡依本發明申請專利範圍所做之均等變化及修飾,仍將不 失本發明之要義所在’亦*齡本發明之精神和範圍,故 都應視為本發明的進一步實施狀況。 【圖式簡單說明】 圖一係為制冷風扇之剖面示意圖。 200921023 圖二係為本發㈣間超導環簡能冰風狀立體透視 示意圖。 圖三係為本發明瞬間超導環保節能冰風扇之a_a剖視 示意圖。 圖四係為本發明瞬間超導環保節能冰風扇第—較佳 施例之剖視示意圖。 圖五係為本發明瞬間超導環保節能冰風扇第二較佳實 施例之剖視示意圖。 圖六係為本發明瞬間超導環保節能冰風扇第三較佳實 施例之前視示意圖。 【主要元件符號說明】 1〜習用冷風扇 11〜箱體 111〜分隔部 112〜冷卻區 113〜排熱區 12〜風扇 13〜致冷晶片 131〜冷接面 132〜熱接面 14〜鰭片 15〜散熱風扇 2、2a、2b、2c〜瞬間超導環保節能冰風扇 21、21a、21b、21c〜殼體 211、211a、211b〜出風D 212、212a〜散熱口 22、22a、22b、22c〜水箱 23、23a、23b、23c〜致冷晶片 231、23la〜冷接面 232、232a〜熱接面 24、24a、24b、24c〜送冷模組 200921023 241、241a、241c〜超導冷管 2421〜開孔 25、25b、25c〜風扇 261〜導散熱鰭片 263〜超導物質 265〜散熱箱 267、268〜鰭片 27、27c〜控制單元 30〜液體 242、242c〜導冷鰭片 243〜超導物質 26、26b、26c〜散熱模組 262、262c〜熱導管 264〜散熱風扇 266〜液體 269〜透氣孔 28、28c〜電源模組 20The first preferred embodiment of the first embodiment of the preferred embodiment of the present invention is different from the instant superconducting environmentally-friendly and energy-saving ice fan of FIG. 2 in that the instantaneous superconducting environmental protection The energy-saving ice fan 2a further includes: a second water tank 22a, at least one second cooling wafer 2, and a plurality of second superconducting cold tubes 241a. The second water tank 22& is disposed inside the casing 21a and is coupled to the plurality of second superconducting cold pipes 241a with respect to the upper portion of the water tank 22. The second tank melon is filled with the same liquid as the tank 22. The second refrigerating wafer 23a is electrically connected to the control unit 27. The cold junction 23u of the second refrigerating wafer 23a is disposed outside the second water tank 22a and attached to the second water tank. The water tank = upper, so that the liquid 3〇 in the second water tank 22a can be rapidly cooled, and the second cold-heating wafer 2 is connected to the heat guide ^262 13 200921023 The thermal energy generated by the second cooling fin 23a is transmitted to the upper surface of the heat dissipation fin 261, and the thermal energy is transmitted through the heat dissipation opening 212a of the housing 21a by the heat dissipation fan 264. The instant superconducting environmental protection and energy saving ice fan is discharged. Outside 2a. The superconducting material 243 is filled in the tube of the second superconducting cold pipe 241a, one end of which penetrates and extends into the second water tank 22a, and the other end of which is disposed above the water tank 22 A plurality of cold-lead fins 242 are disposed through the opening 2421 of the cold-finned fins 242. That is to say, the original superconducting cold pipe 241 and the second superconducting cold pipe 241a are simultaneously penetrated through the plurality of cold guiding fins 242, and the low temperature in the water tank 22 and the second water tank 22a, respectively. And transmitting to the plurality of cold-finned fins 242 at the same time, so that the respective cold-finned fins 242 can more quickly lower the temperature, and the fan 25 passes through the interval of the cold-conductive fins 242 respectively. The low temperature generated by the cold guide fins 242 is carried out by the air outlet 211a of the casing 21a in a cold air manner outside the casing 21a, thereby achieving a faster and lower temperature. The material of the second water tank 22a and the second superconducting cold pipe 241a may be one of iron, copper, iron, steel, stainless steel, aluminum alloy, and titanium alloy. Referring to FIG. 5, FIG. 5 is a cross-sectional view showing a first preferred embodiment of the instant superconducting environmental protection and energy saving ice fan of the present invention. As shown in FIG. 5, FIG. 5 is a difference between the second preferred embodiment of the instant superconducting % guaranteed heat pump and the instant ultra-V% energy saving ice fan of FIG. 2 , the instantaneous superconducting environmental protection and energy saving ice fan The air outlet 211b is located below the casing 21b and corresponds to the teardown module of the 200921023 « 2lb n, and the fan 25b is disposed behind the cooling module 24b. The cold air is separated from the air outlet 211b by the interval between the cold guide fins 242. The water tank 22b is disposed above the cooling module 2牝, and the portion of the cooling and cooling unit 2 that is not provided with the cold-finned fins 242 is inserted into the water tank 22b. It is roughly the instantaneous superconducting of FIG. 2, and the component of the ice fan 2 in the casing 21 is inverted. Based on the principle of cooling air, the superconducting material 243 can be used to more quickly transfer the low temperature generated by the water tank 22b (10) to the cooling module 24b located below the water tank 22b to achieve accelerated cooling efficiency. In addition, the cooling chip 2 disposed on the outside of the water tank 22b, the thermal interface 232, the thermal energy carried by the water tank 22b is discharged from the heat dissipation module 26b above the casing 21b. In addition to the housing 21b, the principle of the hot air upper crucible is further compensated for, and the efficiency of heat dissipation is further accelerated. 6 is a front view of a second preferred embodiment of the instant superconducting environmentally-friendly and energy-saving ice fan 2c of the present invention. Similar to the foregoing embodiments, the utility model also has a housing 21c and a water tank 22c filled with liquid inside. One or more refrigerating chips 23c, a cooling module 24c composed of a plurality of superconducting cold tubes 241c and a plurality of cold guiding fins 242c inserted into the water tank 22c, a fan 25c for blowing cold air, and a control unit 27c, and components such as the power module 28c. The difference between the instant superconducting environmental protection and energy-saving ice fan 2c of the third preferred embodiment and the foregoing embodiments is that the heat dissipation module 26c of the instant superconducting environmental protection and energy-saving ice fan 2c does not have the heat dissipation fins and the dispersion 15 200921023 Hot fan. In contrast, as shown in FIG. 6, the heat dissipation module 26c of the instant superconducting environmental protection and energy saving ice fan 2c is composed of a heat dissipation box 265 including a heat absorbing liquid 266 therein, and a plurality of heat connections connected to the refrigerant chip 23c. The heat pipe 262c is formed on the surface. The heat pipes 262c are end-bonded and contacted to the hot junction of the chilled wafer 23c, and the other end is inserted into the liquid 266 in the heat sink 265. A plurality of heat dissipation fins 267' are further disposed on the heat pipe 262c in the heat dissipation box 265 so that the heat of the heat pipe 262c is quickly transferred and absorbed by the liquid 266 in the heat dissipation box 265. A plurality of heat dissipation fins 268 may also be disposed outside the heat dissipation box 265 to provide a heat dissipation function and appropriately reduce the temperature of the liquid 266 in the heat dissipation box 265. The housing corresponding to the position of the plurality of heat dissipation fins 268 outside the heat dissipation box 265 may be provided with a plurality of vent holes 269 for air circulation. With such a design, the instant superconducting environmentally-friendly and energy-saving ice fan 2c of the present invention generates cold air by the cooling chip 23c, the cooling module 24c and the fan 25c, and the hot junction of the cooling wafer 23c is generated. The heat will be absorbed by the liquid 266 in the heat sink 265 without being discharged to the outside. In this way, the instantaneous superconducting environmentally-friendly and energy-saving ice fan 2c can be used as an indoor unit, and can be placed anywhere in the room without worrying about the heat generated by the hot junction of the cooling chip 23c. Affect the effect of the cold room. Of course, in a preferred embodiment, a temperature control unit (not shown) can be added to the control unit 27c to monitor the temperature of the liquid 266 in the heat dissipation box 265 and the cold air blown by the fan 25c. temperature. Once the temperature of the liquid 266 in the heat sink 265 rises to a predetermined temperature, or the cold air blown by the fan 25c is lower than another predetermined temperature, the control unit 27c will automatically lower or suspend the operating power of the cold 200921023 wafer 2 = To achieve the effect of protection or temperature control. The invention of the present invention provides an instant superconducting environmentally-friendly and energy-saving ice fan 2, which comprises: a casing 2 - a water tank 22, at least a uniform cold crystal 1 23, a second cooling module 24, a fan 25, A heat dissipation module %, and a control unit 27. The casing 21 is in the form of a hollow shell, which further comprises: = tuyere 211, and - a heat sink. The cooling module % further includes: = a superconducting cold tube 241, a plurality of cold guiding fins 242, and a superconducting small one green heat module% further comprising a heat sink fin 26 to 262 a super The conductive material 263 and a heat dissipation fan 264. ~ The water phase 22 is a hollow metal container which is filled with a liquid 3 内部 in the inner space of the second box 22 of the casing, and the liquid 3G in the water tank 22 is rapidly cooled by the cooling 4 23 == is applied to the cooling module 24, and the cooling fan is used to discharge the cold air from the air outlet to the casing. The cooling chip 23 includes a cold junction surface 231 and a surface 232; The connection surface 231 is disposed on the outside of the 哕泱 々 々 又 又 又 又 又 , , , , , , , , , , , , , , , , , , , , , , , , , , , , 外侧 外侧 外侧 外侧 外侧 外侧 外侧 外侧 外侧Is it opposite to the heat sink of the housing 21? The control unit 27 = is connected via the vent 212 and controls its operation. The cooling film 23 is electrically connected to the superconducting cold pipe body of the cooling module 24, and a part of the pipe body penetrates and extends the 41 system into the closed water pipe inner water phase 22. The cold-finned fins 17 200921023 242 are formed in a metal sheet shape, and a plurality of openings 2421 are formed in the upper portion, and the openings 2421 are disposed on the superconducting cold tube 241 by a predetermined distance. The superconducting material 243 is filled in the tube of the superconducting cold tube 241, and the low temperature generated by the inside of the water tank 22 passing through the refrigerating wafer 23 is rapidly transmitted to the superconducting cold tube by the superconducting material 243. 241, which in turn transmits low temperature indirectly to the cold guide fins 242. The heat pipe 262 of the heat dissipation module 26 is a hollow closed tube body filled with the superconducting material 263, one end of which is disposed on the heat connection surface 232 of the refrigerant chip 23, and the other end is provided. Above the heat dissipation fin 261. The heat dissipation fan 264 is disposed on the heat dissipation fin 261 and corresponds to the heat dissipation opening 212 of the housing 21. The heat pipe 262 of the heat dissipation module 26 is configured to carry the heat energy generated by the refrigerant chip 23 away from the heat connection surface 232 through the heat pipe 262, and transmit the heat dissipation surface 261 through the heat dissipation fin 261. The heat dissipation fan 264 provided on the sheet 261 discharges thermal energy to the outside of the casing 21 via the heat dissipation port 212. The above-mentioned embodiments are not intended to limit the scope of application of the present invention. The scope of the present invention should be defined by the content of the material of the present invention and the granules contained in the solution. That is, the equivalent variations and modifications of the scope of the present invention will remain <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; [Simple description of the diagram] Figure 1 is a schematic cross-sectional view of a cooling fan. 200921023 Figure 2 is a schematic perspective view of the superconducting ring of the superconducting ring in this issue (4). Figure 3 is a cross-sectional view of the a_a of the instant superconducting environmental protection and energy saving ice fan of the present invention. Figure 4 is a cross-sectional view showing the first embodiment of the instant superconducting environmentally-friendly and energy-saving ice fan of the present invention. Figure 5 is a cross-sectional view showing a second preferred embodiment of the instant superconducting environmentally-friendly and energy-saving ice fan of the present invention. Fig. 6 is a front view showing a third preferred embodiment of the instant superconducting environmentally-friendly and energy-saving ice fan of the present invention. [Description of Main Components] 1 to conventional cold fan 11 to case 111 to partition 112 to cooling zone 113 to heat exhaust zone 12 to fan 13 to refrigerant chip 131 to cold junction 132 to heat junction 14 to fin 15 to the cooling fan 2, 2a, 2b, 2c to the instant superconducting environmentally-friendly and energy-saving ice fans 21, 21a, 21b, 21c to the casings 211, 211a, 211b to the outlets D 212, 212a to the heat dissipation ports 22, 22a, 22b, 22c~water tanks 23, 23a, 23b, 23c~cooling wafers 231, 23la~cold junctions 232,232a~heat junctions 24,24a,24b,24c~cooling modules 200921023 241,241a,241c~superconducting cold Tube 2421 to opening 25, 25b, 25c to fan 261 to conductive fin 263 to superconducting material 265 to heat sink 267, 268 to fin 27, 27c to control unit 30 to liquid 242, 242c to cold fin 243~ superconducting material 26, 26b, 26c~ heat dissipation module 262, 262c~ heat pipe 264~ cooling fan 266~ liquid 269~ vent hole 28, 28c~ power module 20