200817097 九、發明說明: 【發明所屬之技術領域】 I電霧化 ^發明與用來產生具除g力的帶電微 I置有關。 【先前技術】 國際特許公開WQ 2005/097339 電微教噴霧(太乎〜幵’在形成奈米帶 1〇 電:敌電電極與辅助電極之間力姻壓來放電置:由在供 包蛋的水產生瑞利(Rayleigh)分裂後霧介。、古 吏、准持放 僅含有活性種(自由基 I &種帶電微粒水 各個角落,附著决計九〒長,可飛散到環境空間内 «、脱臭。屬在於該空間内的物體後,有效: 15 =種靜電霧化裝置具有放電電極、 由在:二二在放電電極施加高電壓的高電‘電電極的 化來施加高電屢,使供給至放電部,藉 2〇 次途捏係^有、人謂。這種靜電霧切署心务 氣冷却部冷;:::部與放熱部的熱交換⑻衣:的供 妒^ 口p放電電趣,將結露水供丛= 且成’透過電 一而,這種既有枝 、、σ文电電極的表面。 务,,輔助電極的空間内供仏人、、”必須在配置敌 知加鬲電壓的吝本 、、七3濕氣的空氣,萁__ =旦暴露在含濕氣二”或作為供水途徑的電;; 出現整個裝置的戍 200817097 本增加等問題。 【發明内容】 本發明係以上述誣#上 丄, 來畸為殷鑑而發明,其課韻兔·、自 咼濕度的空氣來&高靜恭+ ^ fe 兒務化的效率,邊提供安全B /CL ^ 的靜電霧化裝置,來隱施y 且低戍冰 丨巧離、保護高電壓源或冷卻诠你 來 濕度環境的影響。 二不弩鳥 本發明有關的靜番♦ 士成 I務化I置,由釋放帶電微粒水 霧化組件及收納這種靜命兩的 里睜電務化組件的外殼組成。靜曾带戈 件,其組成為·放電電極、與上兩 務匕、% 15 與放熱室。這個噴霧室配有靜tr , 助電極;放熱室配有上述冷卻埯^化組件的放電電; 源。利用這個結構可將希望具有=放雜部與上述高電壓 免高濕度空氣的孜熱室分開,轉2噝度交氣的噴霧室及避 20霧室來提高放電電極生成結露心將高蹲度空氣供給至噴 放熱室的零件不受高濕度空氣景^致率’同時保護配置在 最好使喷霧室具有導入… 氣口,、順著第〜及氣口所吸進的\空氣的第一吸氣〇與出 述出氣口釋敌到外面。另、二"IL ’骑上述的帶電微粒 極、冷卻上述放電電極後,凝聚以^對的輔助電 分的冷卻途徑、及在上述放電:J極四周空氣水 電壓,使這種高電壓加壓所凝聚的電極之間施加高 極前端的放電端釋放出帶電微杈的:=静電,來將放電電 内部空間藉由區隔壁與部分的略q包聲源。上述外殼的 Θ t霧化1&件劃分成喷霧室 k Μ的放電電極與輔 從上述出 面’便放熱室具有導入 7 200817097 外部空氣的第二吸氣口與排氣口,可將流動空氣的敌埶介 氣通路與喷霧室裡的氣流流路元全隔離。再使喷霧a…、二 供給上述放電電極高濕度空氣所需的送風途徑。接^具傷 務室可藉由導入面戲度空氣來提兩放電電極生成奸命臭 效率,同時,放熱室又能與這個高濕度空氣隔離:=的 置在放熱室的高電壓源或作為冷卻途彳曼帝 + '、&配 的電氣連接處不受ΐ濕度環境影響,無需特別實施防3 理,即可限制動作女全。 义處 最好在上述喷霧室的第-吸氣口端設計儲 槽。此時,利用上述送風途徑,將上十 J田水 分順著第一吸氣口吸進朝向上述放電;::崎發的水 高濕度的空氣供給至放電電極。 °机動的氣流’使 接著,上述放電電極最好配置在 + 15 20 這樣—來,能使上述放電電極多餘的上方。 述蓄水槽的排錢路於上述喷 '、、”备水因重力回到上 ::用帶留在放電電極上而降低放電性;:成门予!防多餘的結 破利用。 犯,同時使結露水再 氣口 ,上述噴霧室最好利用隔Η查丨\ 口朝向:上述效電電極流動的第…:刀成氣流從第—吸 向上述出氣口流~长汍路與氣流從第一吸氣 有製造包杠r· 机動的弟二流路。卜及轧 在上述隔間^蓄水槽中高濕度、的:^第—流路内配 第二流路_,將上述放電電極所送風途徑; 有效將蓄水挣* 上述迗風途徑的下太…乂、,在 曰的蒸發水供給至敌略“而形成。藉此可 兔電極端,提高帶電微 8 200817097 粒水的生成效率。 在最佳的實施方式下,上述靜電霧化組件具有保持上 述放電電極、上述輔助電極、及維持上述冷卻途徑的支撐 框架,支撐框架收納在形成於上述區隔壁的安裝孔内。上 5 述支撐框架内形成一密封壁,密封壁的背面配有上述冷卻 途徑,同時,上述放電電極穿過這個密封壁,突出到密封 壁的前方,於密封壁前方露出的上述放電電極的前端部與 上述輔助電極因上述密封壁而與上述冷卻部隔離;這個支 撐框架與上述區隔壁將上述外殼劃分成上述喷霧室與上述 10 放熱室,靜電霧化組件只有放電電極的前端部與輔助電極 於喷霧室露出,其餘部分與喷霧室隔離。這個密封壁的外 表面隨著放電電極的外圍,形成突出幅度越來越小的傾斜 面,放電電極上多餘的結露水可以沿著這個傾斜面滑落, 防止放電電極上滯留多餘的結露水。 15 上述密封壁的外表面沿著半徑方向從上述放電電極 四周的頂端朝向外圍某處延伸形成一隔水板,利用這個隔 水板’可將放電電極生成的多餘結露水排放至蓄水槽端。 上述支撐框架的内侧形成一圍繞密封壁外圍的内 筒,將自上述密封壁表面滑落的水誘導至上述蓄水槽端所 20需的誘導板最好於上述内筒的外圍形成。藉此可將多餘的 結露水有效回收至蓄水槽。 接著,上述密封壁最好採用高斷熱性的材料,表面施 以親水處理。這樣一來,能消除密封壁冷卻後於上方生成 的結露水,同時,避免密封壁表面殘留結露水的水滴。 9 200817097 【實施方式】 根據本發明的其一實施方式相關的靜電霧化裝置附 加圖進行說明。如圖1所示,靜電霧化裝置由靜電霧化組 5 件10與收納其組件的外殼100所組成。外殼100的内部藉 由區隔壁102與部分的靜電霧化組件10 ’劃分成彼此隔離 的喷霧室110與放熱室120。喷霧室110具有導入外部空氣 的第一吸氣口 112及將靜電霧化組件10所生成的帶電微粒 喷霧釋放到外面的出氣口 114 ;放熱室120具有為了冷卻 1〇 靜電霧化組件10的熱源而導入外部空氣的第二吸氣口 122 及將熱交換後的空氣排出的排氣口 124。 靜電霧化組件10如圖2〜4所示,具有維持放電電極 20、輔助電極30、及熱交換器40的支撐框架50。放電電 15 極採用鋁、銅、鎢鋼、鈦、不鏽鋼等熱傳導性及導電性高 的材料。支撐框架50係用來將插在區隔壁102的安裝孔内 的靜電霧化組件10固定在外殼100,具有内筒60與矩形 外筒52,矩形外筒52開放的某一侧面由PBT樹脂、聚碳 酸酯樹脂、PPS樹脂等絕緣材料製成。放電電極20配置在 2〇内筒60的中心軸上,前端突出於内筒的前方。輔助電極 30係中央具有圓形窗32的環狀物,圓形窗32的中心配合 内筒60的中心軸,固定在外筒52的前端,沿著放電電極 的軸方向,與放電電極20前端的放電端分開。放電電極 20與輔助電極30分別與配置在放熱室120内的高電壓源 10 200817097 90連接。高電壓源9〇由嫩廢Λ丄 U由、交壓态組成,在放電# 地的輔助電極30之間施 1趣20與接 疋的Ν笔壓,將刍 4.6kV)供給至放電電極2〇 、%壓(如一 1定万文電電極20 iir6山a 各輔助電極3Θ的圓形窗32 而的放電端與 10 場,如後所言’使供給 至放電:!_緣之間產生 而電壓電 電微粒水以喷霧形式從放電2〇上的水帶靜電,將帶 輔助電極30的圓形窗32,轉?釋放出來。這個噴霧穿過 動在喷霧室100内的氣流,再^至⑨霧室110内,順著流 放電電極20係連接端^碭出氣口 114釋放到外面。 方,與來自高電壓源9〇的導複2,設置在分離壁62的前 接端子34,於外筒52的外圍^%連接;輔助電極30係連 導線94連接。 "戍,與來自高電壓源90的 如圖4、5所示’内筒6〇被,# 15向,内部呈現前後分離的八+ 〜著放電電極20的軸方 J刀離壁^ 62的背面收納了熱交換器4〇 b2採一體成形,分離壁 (Peltier effect)的熱電模組級戍熱父換器4〇由具潘第效應 合,使放電電極的溫度冷卻至水敌電電極20與冷卻端結 氣所含的水分凝聚在放電電极,、的露點以下,來將四周空 2〇供給至放電電極20的冷卻途彳<τ<這個熱父換器40設有將水 面分別具備電子電路的一對绝這個熱交換器4〇由在表 上的熱電單元46所組成,故吹纟反C 之間並聯兩個以 所提供的可變電壓來決定的冷^在外殼内的控制模組80 卻。形成冷卻端的一絕緣板迷度將放電電極20冷 妗玫電電極20後端的凸緣 200817097 熱結合;形成放熱端的另一 這個放熱板48如圖-、、毒板44與放熱板48熱結合。 上,包括放電電極2。:: ’被螺絲54固定在支標框架50 在放熱板48與分離壁H二24 ’熱交換器40也維持 高的鋁或氮化銘组成4 9。、纟巴緣板42、44由熱傳導性 ^ 、 成。控制模組80押制埶交拖哭 便將配合環境溫度與環境 4^熱40,以 極20上凝聚足夠水量'、、、、虽>-度,即可在放電電 的凸緣24的周圍被酉己置二持。放電電極20後端 之間的封裝零件26所包圍7 ϋ而的絕緣板42與分離壁62 熱交換器40藉由於从丸b 路形成的端子45、47 H ^的絕緣板44表面的電子電 連接。 >、來自控制模組80的導線85、87電 分離壁62前方的外 15 20 60—體成形,放面的密封壁64與内筒 ^ 〇貝牙岔封壁64。密封壁64採用 的====:斷熱材料,放電電㈣ , 1Π 〇 ^ , *封壁64的内側,這樣一來,靜電 ’、方電電極20的前端、輔助電極30、及密 =64的W方在喷霧室11〇露出,其他部分與喷霧室ιι〇 ㈣H藉由將靜電霧化组件1〇安裝在外殼1〇〇内的 文衣孔104 ’使支撐框架%的外圍框、密封壁料、分離壁 62與外叙1〇〇的區隔壁1〇2連接,將外殼1⑻的内部分成 噴霧室110及放熱室120。此時,熱交換器4〇裡的放熱端 的絕緣板44連同放熱板48外露於放熱室12〇 ;而冷卻端 12 200817097 的絕緣板42則位在分離壁62與絕緣板44之間,藉此既與 放熱室120也和喷霧室110隔離。同時,輔助電極30的連 接端子34及熱交換器40的端子45、47位在支撐框架50 外侧的放熱室120端,與喷霧室110隔離;放電電極的連 5 接端子22因密封壁64而與喷霧室110隔離。此外,部分 的密封壁64如圖6所示,形成缺塊67,以使連接端子22 露出,讓連接端子22的高電壓源90的連接作業變容易; 連接後,利用絕緣性的合成樹脂材料70,將這個缺塊67 及其他開口密封,藉由含合成樹脂材料的密封壁64將連接 ίο端子22與喷霧室110隔離。這樣一來,除了高電壓源90、 控制模組80的電子電路,這些與靜電霧化組件10之間的 電連接處也能與喷霧室110隔離,不受供給至喷霧室110 内的高濕度空氣所影響,避免電子電路或電連接處因濕氣 而受損。 15 這樣組成的靜電霧化組件10,如圖1所示,將放電電 極20的轴方向以水平狀配置在外殼100内,來自喷霧室 110下端的高濕度空氣與放電電極20接觸後,空氣中的水 分在放電電極20上凝聚,以便將水供給至放電電極20, 2〇 利用放電電極20與輔助電極30之間施加的高電壓,將帶 電微粒水釋放至喷霧室110内,順著從第一吸氣口朝向出 氣口流動的氣流釋放到外面。 放熱室120具有排氣扇124,能製造使第二吸氣口 122 所吸進的空氣從排氣口 124排出的氣流,將放熱板48或高 13 200817097 電壓源90曝露在這個氣流裡來促進放熱。 外露在喷霧室110的密封壁64的前方,沿著圍繞放電 電極20的中間朝向周圍邊緣,呈現突出幅度越來越小的弧 5 狀曲面,使放電電極20上多餘的結露水往下方滑落。再 者,密封壁64沿著半徑方向延伸,形成一隔水板65,來 將多餘的結露水儘早滑落到内筒60的外侧。與其有關,内 筒60外圍某一處在隔水板65的延長線上形成一延伸至下 方的誘導板66,促使多餘的結露水回收到形成在喷霧室 ίο 110下端的蓄水槽115。密封壁64與施以合成樹脂的部分 採用斷熱性高的材料,阻斷放電電極20的熱來避免密封壁 64冷卻。 如圖1所示,喷霧室110的下方設有風扇113,將來 15自蓄水槽116的水蒸氣,順著第一吸氣口 112所吸進的氣 流,供給高濕度的空氣至靜電霧化組件10端。喷霧室110 被隔間106區分成將空氣往靜電霧化組件10端流動的第一 流路F1與將空氣往出氣口 114端流動的第二流路F2,與 靜電霧化組件10相對的隔間106形成一開口 108,能將靜 20電霧化組件10所釋放的帶電微粒喷霧送往開口第二流路 F2。第一流路F1配有風扇114,緊捱著設置在上流端的風 扇113,將高濕度的空氣供給至靜電霧化組件10端,同時 使靜電霧化組件10所產生的帶電微粒喷霧送往第二流路 F2端。風扇114與風扇113形成送風途徑,促使蓄水槽116 14 200817097 產生水蒸氣,將高濕度的空氣供給至靜電霧化組件ίο的放 電電極20。送風途徑由任一方的風扇組成皆可。 上方的第一流路F1係將高濕度的空氣供給至放電電極 5 20的流路,另一方面也可以作為排水通路,將放電電極20 生成的多餘結露水送回蓄水槽116,邊將多餘的結露水再 利用,邊繼續促使放電電極20有效形成結露水。 此外,只要將上述密封壁64的表面形成細微凹凸,再 1〇 進行親水處理,就能使結露水變成大水滴而不會滯留在密 封壁64的表面,有效將結露水回收至蓄水槽116端。 同時,在本實施方式下,以供給高濕度的空氣而將蓄 水槽116於外殼100内形成為例,本發明並非只限於此, 15 若在外面可利用高濕度的供給源,如加濕器時,就能取消 蓄水槽,而在外殼的一端設置連接這個供給源的連接口。 再者,在上述的實施方式下,以下述為例:在外殼100 内配置靜電霧化組件10,藉由於外殼100内形成的區隔壁 2〇 102與部分的靜電霧化組件將外殼100分離成利用高濕度 空氣的喷霧室110及與這個喷霧室隔離的放熱室120,本 專利申請所公開的靜電霧化組件的結構,特別是採用分離 壁62或密封壁64,將放電電極20前端與輔助電極30所 處的空間與含熱交換器40等其他零件所處的空間隔離的 15 200817097 結構,除了圖中所示,也適用於其他的使用方式。如:在 可使用浴室般高濕度空氣的高濕度空間及與該空間隔離的 低濕度空間之間的範圍内配置靜電霧化組件,這樣一來, 只有放電電極20與輔助電極露在高濕度空間,能有效達到 5靜電霧化,同時又能保護電子電路或電連接部等其他零件 與高濕度環境隔離。在這種構想下,連靜電霧化組件10本 身的結構也變有用了。 這種靜電霧化組件的結構意指:具有在保持放電電極 20、輔助電極30、熱交換器40的支撐框架50上,將支撐 ίο 框架50所包圍的空間,沿著放電電極的轴方向劃分成前後 二個區域的分離壁62與在分離壁62前方的密封壁64的結 構,在分離壁62的背面配置熱交換器40,放電電極的後 方由分離壁62支撐,輔助電極30由支撐框架的外框支撐。 放電電極20貫穿分離壁62及密封壁64使其前方與輔助電 15 極分開。用來將放電電極20與外部高壓電源90連接的連 接端子22位在分離壁62與密封壁64之間;用來將輔助電 極30與外部高壓電源90連接的連接端子34位在支撐框架 50的外圍。熱交換器由具潘第效應的熱電模組組成,與外 部控制模組電連接的端子45、47位在分離壁62背面的支 2〇 撐框架50的外侧。這種結構能只讓放電電極20的前端與 輔助電極30外露在支撐框架50所包圍且為密封壁64前方 的區域,使其他零件與密封壁64的背面隔離。 【圖式簡單說明】 16 200817097 圖1表示與本發明的其一實施方式有關的靜電霧化裝置 的切面圖。 圖2表示使用同上的靜電霧化組件的侧面圖。 圖3同上的靜電霧化組件的正面圖。 5 圖4同上的靜電霧化組件的縱切面圖。 圖5同上的靜電霧化組件的橫切面圖。 圖6表示同上的靜電霧化組件在安裝前的正面圖。 【主要元件符號說明】 10 靜電霧化組件10 外殼100 區隔壁102 安裝孔104 15 喷霧室110 2〇 放熱室120 放電電極20 隔間106 開口 108 第一吸氣口 112 風扇113 出氣口 114 蓄水槽115 蓄水槽116 第二吸氣口 122 排氣口 124 連接端子22 17 200817097 5 10 15 輔助電極30 熱交換器40 支撐框架50 内筒60 合成樹脂材料70 控制模組80 高電壓源90 第一流路F1 第二流路F2 凸緣24 封裝零件26 圓形窗32 連接端子34 絕緣板42、44 端子45、47 熱電單元46 放熱板48 矩形外筒52 螺絲54 分離壁62 密封壁64 隔水板65 誘導板66 缺塊67 導線85、87 導線92 導線94 18 20200817097 IX. Description of the invention: [Technical field to which the invention pertains] I Electrospray The invention is related to the use of a charged micro-distribution with a force of g. [Prior Art] International Licensed Open WQ 2005/097339 Electric micro-teaching spray (Too ~ ~ 'in the formation of nano-belt 1 〇 electricity: between the enemy electric electrode and the auxiliary electrode to discharge the pressure: by the egg The water produces Rayleigh splitting and fogging. The ancient cockroach and quasi-holding contain only active species (free radicals I & kinds of charged particles in all corners of the water. The adhesion is determined to be nine inches long and can be scattered into the environmental space. «, deodorization. Dependent on the object in the space, effective: 15 = kind of electrostatic atomization device with a discharge electrode, by the high voltage "electrical electrode applied high voltage on the discharge electrode" It is supplied to the discharge section, and it is said that the static electricity mist is cut off by the cold air; The p-discharge is interesting, and the dew condensation is supplied to the cluster = and becomes 'transmission through electricity. The surface of the electrode with the branch and the sigma. The service is provided in the space of the auxiliary electrode." Configure the scorpion of the enemy's twisted voltage, and the air of the 7-3 moisture, 萁__ = once exposed The invention contains the moisture or the electricity as the water supply route; the invention has the problem of the increase of the whole device 戍200817097. [Invention] The present invention is invented by the above-mentioned 诬#丄丄, and is invented by Yin Jian. Self-humidity air comes to & Gao Jinggong + ^ fe efficiency, while providing a safe B /CL ^ electrostatic atomization device to hide y and low hail, protect high voltage source or cool Explain the impact of your humidity environment. The second 弩 本 本 本 本 本 ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ 释放 释放 释放 释放 释放 释放 释放 释放 释放 释放 释放 释放 释放 释放 释放 释放The outer shell is composed of static parts, which are composed of a discharge electrode, a discharge electrode, a top 15 and a heat release chamber. The spray chamber is equipped with a static tr and an auxiliary electrode; the exothermic chamber is equipped with the above-mentioned cooling unit. Discharge electricity; source. With this structure, it is possible to separate the heat-dissipating chamber which is required to have the =-distributing portion from the above-mentioned high-voltage free high-humidity air, and to rotate the spray chamber of the second-degree air supply and avoid the mist chamber to increase the condensation of the discharge electrode. The heart supplies high-pitched air to the heat of discharge The parts are not subject to the high humidity air view rate. At the same time, the protection is arranged so that the spray chamber has the inlet, the air inlet, the first air suction and the first air intake that is sucked in along the first and the air ports. The gas port releases the enemy to the outside. The other, the second "IL' rides the above-mentioned charged particle electrode, cools the above-mentioned discharge electrode, and condenses the cooling path of the auxiliary electric component of the pair, and the above-mentioned discharge: the air water voltage around the J pole, The discharge end of the high-electrode front end between the electrodes which are agglomerated by such high-voltage pressurization releases the charged micro-electrode:=electrostatic electricity, and the discharge electric internal space is separated by a partition wall and a part of the slightly q-package sound source. The 外壳t atomization 1& of the outer casing is divided into a discharge chamber of the spray chamber k 与 and a secondary suction port and an exhaust port having an external air introduced into the outer surface of the above-mentioned surface, and the flow air can be introduced. The enemy air passage is completely isolated from the air flow path in the spray chamber. Further, the sprays a... and 2 are supplied to the air supply path required for the high-humidity air of the discharge electrode. The contact with the injury room can introduce the two discharge electrodes to generate the smothering efficiency, and at the same time, the heat release chamber can be isolated from the high humidity air: = the high voltage source placed in the heat release chamber or The cooling connection between the Mandi + ', && electrical connections is not affected by the humidity environment, you can limit the action of women without special protection. It is preferable to design a reservoir at the first suction port end of the spray chamber. At this time, the upper air channel is sucked into the discharge along the first air intake port by the air blowing means;:: the water of the high temperature is supplied to the discharge electrode. The maneuvering air flow is such that the discharge electrode is preferably disposed at + 15 20 such that the discharge electrode is superposed above. The water draining path of the water storage tank is in the above-mentioned spray ', and the water supply is returned to the upper side by gravity: the belt is left on the discharge electrode to reduce the discharge property; the door is given to prevent the excess from being broken and utilized. In order to make the dew condensation water re-vent, the spray chamber is preferably used for the inspection of the port. The orientation of the above-mentioned electric electrode is: the flow of the knife into the air flow from the first to the outlet, the long circuit and the air flow from the first The inhalation has a second-stage flow path for manufacturing the package bar r·motorized. The rolling and the high-humidity in the storage tank of the above-mentioned compartment, the second flow path _ in the first-flow path, and the air supply path of the discharge electrode; Effectively, the water will be earned. * The above-mentioned hurricane path is too... 乂, and the evaporating water in the sputum is supplied to the enemy. Thereby, the rabbit electrode end can be used to improve the generation efficiency of charged water. In a preferred embodiment, the electrostatic atomization module has a support frame that holds the discharge electrode, the auxiliary electrode, and the cooling path, and the support frame is housed in a mounting hole formed in the partition wall of the partition. A sealing wall is formed in the support frame, and the cooling passage is disposed on the back surface of the sealing wall. At the same time, the discharge electrode passes through the sealing wall and protrudes to the front of the sealing wall, and the front end of the discharge electrode is exposed in front of the sealing wall. And the auxiliary electrode is separated from the cooling portion by the sealing wall; the support frame and the partition wall divide the outer casing into the spray chamber and the 10 heat release chamber, and the electrostatic atomization assembly only has a front end portion of the discharge electrode and auxiliary The electrodes are exposed in the spray chamber and the remainder is isolated from the spray chamber. The outer surface of the sealing wall forms an inclined surface with a smaller protruding depth along the periphery of the discharge electrode, and excess dew condensation water on the discharge electrode can slide down along the inclined surface to prevent excess dew condensation water from remaining on the discharge electrode. 15 The outer surface of the sealing wall extends from the top end of the discharge electrode toward the periphery to form a water blocking plate in the radial direction, and the water-repellent plate is used to discharge excess dew condensation water generated by the discharge electrode to the water storage tank end. The inner side of the support frame forms an inner cylinder surrounding the periphery of the sealing wall, and the induction plate required to induce water sliding from the surface of the sealing wall to the water reservoir end 20 is preferably formed at the outer periphery of the inner cylinder. This allows the excess dew condensation water to be efficiently recovered to the reservoir. Next, the sealing wall is preferably made of a material having a high heat-breaking property, and the surface is subjected to a hydrophilic treatment. In this way, the dew condensation water generated on the upper side after the sealing wall is cooled can be eliminated, and at the same time, the water droplets remaining on the surface of the sealing wall can be prevented from dew condensation. [Embodiment] An electrostatic atomization device according to an embodiment of the present invention will be described with reference to the accompanying drawings. As shown in Fig. 1, the electrostatically atomizing device is composed of an electrostatic atomizing group 5 and a casing 100 accommodating its components. The interior of the outer casing 100 is divided into a spray chamber 110 and a heat release chamber 120 separated from each other by a partition wall 102 and a portion of the electrostatic atomizing assembly 10'. The spray chamber 110 has a first air inlet 112 for introducing external air and an air outlet 114 for discharging the charged particle spray generated by the electrostatic atomizing assembly 10 to the outside; the heat releasing chamber 120 has an electrostatic atomizing assembly 10 for cooling 1〇. The heat source is introduced into the second air inlet 122 of the outside air and the air outlet 124 that discharges the heat exchanged air. As shown in Figs. 2 to 4, the electrostatic atomizing unit 10 has a support frame 50 for maintaining the discharge electrode 20, the auxiliary electrode 30, and the heat exchanger 40. The discharge pole 15 is made of materials such as aluminum, copper, tungsten steel, titanium, stainless steel, etc., which have high thermal conductivity and high electrical conductivity. The support frame 50 is used to fix the electrostatic atomizing assembly 10 inserted in the mounting hole of the partition wall 102 to the outer casing 100, and has an inner cylinder 60 and a rectangular outer cylinder 52. One side of the rectangular outer cylinder 52 is open by PBT resin, Made of insulating materials such as polycarbonate resin and PPS resin. The discharge electrode 20 is disposed on the central axis of the inner cylinder 60, and the front end protrudes forward of the inner cylinder. The auxiliary electrode 30 is an annular body having a circular window 32 at the center, and the center of the circular window 32 is fitted to the central axis of the inner cylinder 60, and is fixed to the front end of the outer cylinder 52 along the axial direction of the discharge electrode and the front end of the discharge electrode 20. The discharge ends are separated. The discharge electrode 20 and the auxiliary electrode 30 are respectively connected to a high voltage source 10 200817097 90 disposed in the heat release chamber 120. The high voltage source 9〇 is composed of the tender waste U and the alternating pressure state, and between the auxiliary electrodes 30 of the discharge #1, the Ν 与 与 与 与 与 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍 刍〇, % pressure (such as a 1 fixed Wanwen electric electrode 20 iir6 mountain a each auxiliary electrode 3 Θ circular window 32 and the discharge end and 10 fields, as will be said later, 'supply to discharge:! _ edge between The voltage electro-electric particulate water is electrostatically charged in the form of a spray from the water on the discharge port 2, and the circular window 32 with the auxiliary electrode 30 is released. This spray passes through the air flow in the spray chamber 100, and then In the mist chamber 110, the outlet port 114 is discharged to the outside along the flow discharge electrode 20, and the guide 2 from the high voltage source 9 is disposed at the front terminal 34 of the separation wall 62. The peripheral electrode 52 is connected to the periphery of the outer tube 52. The auxiliary electrode 30 is connected to the wire 94. "戍, and the internal pressure from the high voltage source 90 as shown in Figs. 4 and 5, the inner tube 6〇, #15向, internal representation The front and rear separated eight + ~ the discharge side of the discharge electrode 20 J knife away from the wall ^ 62 on the back of the heat exchanger 4 〇 b2 integrated forming, separation wall (Pelt The thermoelectric module level of the ier effect is replaced by a Pan-first effect, so that the temperature of the discharge electrode is cooled until the water contained in the enemy electrode 20 and the cooling end is condensed on the discharge electrode, Below the dew point, the cooling path for supplying the surrounding space to the discharge electrode 20 is <τ< This hot-replacer 40 is provided with a pair of heat exchangers 4 each having an electronic circuit on the water surface. The upper thermoelectric unit 46 is composed, so that the control module 80 in the outer casing is connected in parallel with the variable voltage provided by the blowing reverse C. The insulation plate forming the cooling end will discharge The electrode 20 is cold-bonded to the flange 200817097 at the rear end of the electrode 20; the other heat-dissipating plate 48 forming the heat-dissipating end is thermally coupled to the heat-dissipating plate 48. The upper portion includes the discharge electrode 2.:: ' It is fixed by the screw 54 to the support frame 50. The heat release plate 48 and the separation wall H 24 'heat exchanger 40 are also maintained at a high aluminum or nitriding composition 49. The slab edge plates 42 and 44 are thermally conductive. Cheng. Control module 80 is forced to cope with the environment and the environment 4 ^Hot 40, by condensing a sufficient amount of water on the pole 20 ',,, and > degrees, it can be placed around the flange 24 of the discharge electric power. The packaged parts between the rear ends of the discharge electrodes 20 The insulating plate 42 and the partition wall 62 surrounded by 26 heat exchangers 40 are electrically connected by the surface of the insulating plate 44 of the terminals 45, 47 H ^ formed from the ball b. > From the control module 80 The wires 85, 87 are electrically formed in the front of the wall 62, and are formed by the outer surface of the sealing wall 64 and the inner tube. The sealing wall 64 is made of ====: heat-dissipating material, discharge electric (four), 1Π 〇^, * inside of the sealing wall 64, so that the static electricity, the front end of the square electric electrode 20, the auxiliary electrode 30, and the dense = The W side of 64 is exposed in the spray chamber 11 , and the other part and the spray chamber 四 〇 四 四 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉 藉The sealing wall material and the separating wall 62 are connected to the partition wall 1〇2 of the outer casing 1 to divide the inside of the outer casing 1 (8) into a spray chamber 110 and a heat releasing chamber 120. At this time, the insulating plate 44 of the heat releasing end in the heat exchanger 4 is exposed to the heat releasing chamber 12 连同 together with the heat releasing plate 48; and the insulating plate 42 of the cooling end 12 200817097 is located between the separating wall 62 and the insulating plate 44, whereby It is isolated from both the heat release chamber 120 and the spray chamber 110. At the same time, the connection terminal 34 of the auxiliary electrode 30 and the terminals 45, 47 of the heat exchanger 40 are located at the end of the heat release chamber 120 outside the support frame 50, and are isolated from the spray chamber 110; the connection terminal 22 of the discharge electrode is closed by the sealing wall 64. It is isolated from the spray chamber 110. Further, as shown in FIG. 6, a part of the sealing wall 64 forms a missing block 67 to expose the connection terminal 22, thereby facilitating the connection work of the high voltage source 90 of the connection terminal 22; after the connection, an insulating synthetic resin material is used. 70. The missing block 67 and other openings are sealed, and the connection ίο terminal 22 is isolated from the spray chamber 110 by a sealing wall 64 containing a synthetic resin material. In this way, in addition to the high voltage source 90, the electronic circuit of the control module 80, the electrical connection between the electrostatic atomization assembly 10 and the electrostatic atomization assembly 10 can be isolated from the spray chamber 110 and not supplied to the spray chamber 110. High humidity air is used to prevent damage to electronic circuits or electrical connections due to moisture. 15 As shown in FIG. 1, the electrostatic atomizing unit 10 having the above configuration is arranged such that the axial direction of the discharge electrode 20 is horizontally disposed in the outer casing 100, and the high-humidity air from the lower end of the spray chamber 110 is in contact with the discharge electrode 20, and the air The water in the water is condensed on the discharge electrode 20 to supply water to the discharge electrode 20, and the charged particulate water is released into the spray chamber 110 by the high voltage applied between the discharge electrode 20 and the auxiliary electrode 30. The airflow flowing from the first intake port toward the air outlet is released to the outside. The heat release chamber 120 has an exhaust fan 124, and can generate an air flow for discharging the air sucked in the second intake port 122 from the exhaust port 124, and exposing the heat release plate 48 or the high voltage source 90 9017 to the air flow to promote the air flow. Exothermic. Exposed in front of the sealing wall 64 of the spray chamber 110, along the middle of the discharge electrode 20 toward the peripheral edge, an arc-shaped curved surface with a smaller and smaller protruding amplitude is present, so that the excess dew condensation water on the discharge electrode 20 slides downward. . Further, the sealing wall 64 extends in the radial direction to form a water blocking plate 65 to slide the excess dew condensation water to the outside of the inner cylinder 60 as early as possible. In connection with this, an extension plate extending to the lower side of the water-repellent plate 65 is formed at a position on the periphery of the inner cylinder 60 to cause excess dew condensation water to be recovered to the water storage tank 115 formed at the lower end of the spray chamber ίο 110. The sealing wall 64 and the portion to which the synthetic resin is applied are made of a material having high heat-insulating property, and the heat of the discharge electrode 20 is blocked to prevent the sealing wall 64 from being cooled. As shown in FIG. 1, a fan 113 is disposed below the spray chamber 110, and in the future, 15 water vapor from the water storage tank 116 is supplied to the airflow of the high-humidity air to the electrostatic atomization along the airflow sucked by the first air inlet 112. Component 10 end. The spray chamber 110 is divided by the compartment 106 into a first flow path F1 for flowing air toward the end of the electrostatic atomizing assembly 10 and a second flow path F2 for flowing air to the end of the air outlet 114, opposite to the electrostatic atomizing assembly 10. The space 106 forms an opening 108 for delivering the charged particle spray released by the static 20 electrospray assembly 10 to the open second flow path F2. The first flow path F1 is provided with a fan 114, and next to the fan 113 disposed at the upstream end, the high-humidity air is supplied to the end of the electrostatic atomizing assembly 10, and the charged particle spray generated by the electrostatic atomizing assembly 10 is sent to the first Second flow path F2 end. The fan 114 and the fan 113 form a blowing path, causing the water storage tank 116 14 200817097 to generate water vapor, and the high humidity air to the discharge electrode 20 of the electrostatic atomizing unit ί. The air supply path can be composed of either fan. The upper first flow path F1 supplies high-humidity air to the flow path of the discharge electrode 520, and can also serve as a drain path, and the excess dew condensation water generated by the discharge electrode 20 is sent back to the water storage tank 116, and the excess is The dew condensation water is reused while continuing to cause the discharge electrode 20 to effectively form dew condensation water. Further, if the surface of the sealing wall 64 is formed with fine concavities and convexities, and the hydrophilic treatment is performed, the dew condensation water can be made into large water droplets without being retained on the surface of the sealing wall 64, and the dew condensation water can be efficiently recovered to the end of the water storage tank 116. . Meanwhile, in the present embodiment, the water storage tank 116 is formed in the outer casing 100 by supplying air of high humidity, and the present invention is not limited thereto, and a high-humidity supply source such as a humidifier may be used outside. At this time, the water storage tank can be eliminated, and a connection port connecting the supply source is provided at one end of the outer casing. Furthermore, in the above embodiment, the electrostatic atomization assembly 10 is disposed in the outer casing 100 by separating the outer casing 100 into a partial partition wall 2 102 formed in the outer casing 100 and a part of the electrostatic atomizing assembly. The spray chamber 110 of high humidity air and the heat release chamber 120 isolated from the spray chamber, the structure of the electrostatic atomization assembly disclosed in the present patent application, in particular, the separation wall 62 or the sealing wall 64, the front end of the discharge electrode 20 The structure of the 2008 17097, which is isolated from the space in which the auxiliary electrode 30 is located, and the space in which the other components such as the heat exchanger 40 are located, is also applicable to other modes of use, except as shown in the drawings. For example, the electrostatic atomizing assembly is disposed in a range between a high-humidity space in which a bathroom-like high-humidity air can be used and a low-humidity space isolated from the space, so that only the discharge electrode 20 and the auxiliary electrode are exposed to a high-humidity space. It can effectively achieve 5 electrostatic atomization, and at the same time protect other parts such as electronic circuits or electrical connections from high humidity environment. Under this concept, the structure of the electrostatic atomizing unit 10 itself becomes useful. The structure of such an electrostatic atomizing assembly means that the space surrounded by the support frame 50 is divided on the support frame 50 holding the discharge electrode 20, the auxiliary electrode 30, and the heat exchanger 40, along the axial direction of the discharge electrode. The structure of the separation wall 62 in the front and rear two regions and the sealing wall 64 in front of the separation wall 62, the heat exchanger 40 is disposed on the back surface of the separation wall 62, the rear of the discharge electrode is supported by the separation wall 62, and the auxiliary electrode 30 is supported by the frame Frame support. The discharge electrode 20 penetrates the separation wall 62 and the sealing wall 64 to separate the front side from the auxiliary electrode 15 . A connection terminal 22 for connecting the discharge electrode 20 to the external high-voltage power source 90 is located between the separation wall 62 and the sealing wall 64; a connection terminal 34 for connecting the auxiliary electrode 30 to the external high-voltage power source 90 is located at the support frame 50. periphery. The heat exchanger is composed of a thermoelectric module having a Pan-effect, and the terminals 45, 47 electrically connected to the external control module are located outside the support frame 50 on the back of the separation wall 62. This configuration can expose only the front end of the discharge electrode 20 and the auxiliary electrode 30 to the area surrounded by the support frame 50 and in front of the sealing wall 64, so that the other parts are isolated from the back surface of the sealing wall 64. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional view showing an electrostatic atomization apparatus according to an embodiment of the present invention. Figure 2 shows a side view of an electrostatic atomizing assembly using the same. Figure 3 is a front elevational view of the electrostatic atomizing assembly of the same. 5 Figure 4 is a longitudinal section of the electrostatic atomizing assembly of the same. Figure 5 is a cross-sectional view of the electrostatic atomizing assembly of the same as above. Figure 6 shows a front view of the electrostatic atomizing assembly of the above prior to installation. [Main component symbol description] 10 Electrostatic atomization assembly 10 Housing 100 Zone partition 102 Mounting hole 104 15 Spray chamber 110 2〇 Heat release chamber 120 Discharge electrode 20 Compartment 106 Opening 108 First intake port 112 Fan 113 Air outlet 114 Sink 115 Water tank 116 Second air inlet 122 Exhaust port 124 Connection terminal 22 17 200817097 5 10 15 Auxiliary electrode 30 Heat exchanger 40 Support frame 50 Inner cylinder 60 Synthetic resin material 70 Control module 80 High voltage source 90 First stream Road F1 Second flow path F2 Flange 24 Package part 26 Round window 32 Connection terminal 34 Insulation board 42, 44 Terminal 45, 47 Thermoelectric unit 46 Heat release plate 48 Rectangular outer cylinder 52 Screw 54 Separation wall 62 Sealing wall 64 Water barrier 65 induction plate 66 missing piece 67 wire 85, 87 wire 92 wire 94 18 20