•M373464 五、新型說明: 【新型所屬之技術領域】 特別是有關於一種 本創作是有關於一種冷部系統 具有霧化裝置之冷卻系統。 【先前技術】• M373464 V. New description: [Technical field of new type] Especially related to one. This creation is about a cold system with a cooling system with an atomizing device. [Prior Art]
2地球的溫室效應曰漸的提高,導致整個環境中 的>皿度提升。因此’冷氣機被廣泛的運祕室内空間中, :降低室内空間的溫度。而冷氣機為一獨立的壓縮式致 冷系統,於運行時,於冷氣機的蒸發器上會凝 出冷凝水。 冷氣機滴水的問題,困擾著許多人,常常有住戶抱 怨,位於下層鄰居,因冷氣常滴水而吵的不得安寧。因 此,各縣市政府環保單位已對此現象,冑定相關之法條 及罰則。 為避免冷凝水落入地面,造成環境污染,甚至遭到 相關單位的處罰。多數業者會於冷氣機之排水端設置一 ^水裝置’如第1圖所示。其裝置具有一冷氣機2〇、一 過遽器30及一排水器4〇,而過濾器係裝置於冷氣機2〇 的出水口 21 ’以承接冷氣機20之出水口 21所排放的冷 凝水’且將冷凝水過濾後流入排水器40蓄積。此外,排 水器40具有一抽水馬達41及一出水管42。當冷凝水蓄 積至預定高度時’抽水馬達41即會啟動,以將冷凝水由 出水管42排出洩除。 3 M373464 雖上述排水裝置具有將冷凝水導出洩除的功效,但 是卻無法消除冷凝水,甚至利用冷凝水提升冷氣機散熱 效能。 有鑑於上述缺點’有業者提出一種於室外散熱風扇 軸上安裝霧化盤’並將冷凝水導入霧化盤内,藉由室外 散熱風扇帶動霧化盤旋轉使水滴霧化的裝置。然而,由 於風扇轉速慢,離心力不足,使水滴霧化率不足而使大 部分冷凝水仍為水滴流出。 此外’亦有業者提出以超音波霧化之方式霧化冷凝 水,再使霧化分子接觸於散熱片上以降低散熱片之溫 度,然而,因以超音波霧化之方式耗能較高,不符合經 濟效益。此外,經超音波霧化方式所產生的水霧分子顆 粒大小並不均勻,當較大顆粒之水霧分子碰觸於散熱片 上時,會漸漸沉積於散熱片上而產生積水,導致散熱片 產生金屬腐蝕的現象。 【新型内容】 有鑑於上述習知技藝之問題,本創作之目的就是在 提供一種冷卻系統,以解決習知技藝霧化效率不佳或容 易產生積水於散熱片上的問題。 =本=之-目的,提i種冷卻系統, 一霧化裝置、一出水管路及-散熱元件。致 =裝置產生-冷凝水,並包括—集水盤1水盤 载冷部水。散熱元件係冷卻致冷裝f,以避免致 M373464 …、霧化裝置包括一霧化片、一塵 槽。壓雷麒動分杜在姓也咖 澄冤驅動7C件及一水 堅電驅動兀件係帶動霧化片產生振動 、接集水盤及水槽,以輸送冷凝水至水槽。 ’、 在隹ΪΓ致冷裝置更包括—抽水馬達,該抽水馬達設 在集水盤與讀之間,並㈣转水於出水流動。 朝散^外杜冷卻系統更包含—風扇裝置,其係帶動水霧 朝散熱70件之方向移動。 其中,冷卻系統還包括一過濾元件,其設 2產生冷凝水之位置與讀之間,喊元件係'用以i 除混合冷凝水之雜質。 其中’過滤元件具有一遽水槽及一滤棉,遽水槽儲 存冷凝水’濾棉吸附濾水槽内的冷凝水之雜質。 其中,冷卻系統更具有一溫度感測元件,其係偵測 散熱元件之溫度’使該霧化之裝置據以控制霧化水滴之 產生量。 中’務化水滴之顆粒直徑為1私m至1 〇〇 y m。 其中’霧化裝置包括一驅動電路’一固定座及一水 槽,驅動電路係控制壓電驅動元件作動,該壓電驅動元 件之一侧係固設於該固定座,該水槽係容置該冷凝水。 其中’霧化裝置包括一液珠輸送管,該液珠輸送管 係將儲存於該水槽内之冷凝水往上輸送,並於該液珠輸 送管之管口處形成一曲面水膜而吸附於該霧化片之一 侧。 5 M373464 其中,致冷裝置包括一壓縮機、一凝結器、一 閥、一蒸發器及一循環管路,循營 冷 乂 循環管路係連通壓縮機、凝結器:瞭關一、I媒, 連回壓縮機’且循環管路與散熱元件進行熱交、:器’再 行熱—冷媒’冷媒係與散熱元件進2 The earth's greenhouse effect is gradually increasing, resulting in an increase in the overall environment. Therefore, the air conditioner is widely used in the secret interior space: to reduce the temperature of the indoor space. The air conditioner is a separate compression refrigeration system that condenses condensate on the evaporator of the air conditioner during operation. The problem of dripping water in air conditioners is plaguing many people. Often there are residents who complain, and they are located in the lower neighbors. They are not peaceful because of the cold air. Therefore, the environmental protection units of the counties and municipalities have already delineated the relevant laws and penalties for this phenomenon. In order to prevent condensed water from falling into the ground, it caused environmental pollution and even was punished by the relevant units. Most operators will install a water device on the drain end of the air conditioner as shown in Figure 1. The device has an air conditioner 2, a filter 30 and a drain 4, and the filter is installed in the water outlet 21' of the air conditioner 2 to receive the condensed water discharged from the water outlet 21 of the air conditioner 20. 'And the condensed water is filtered and then flows into the drainer 40 to accumulate. Further, the drainer 40 has a pumping motor 41 and an outlet pipe 42. When the condensed water is accumulated to a predetermined height, the pumping motor 41 is activated to discharge the condensed water from the outlet pipe 42. 3 M373464 Although the above drainage device has the effect of draining the condensed water, it does not eliminate the condensed water, and even uses the condensed water to improve the cooling efficiency of the air conditioner. In view of the above disadvantages, a manufacturer has proposed a device for mounting an atomizing disk on an outdoor cooling fan shaft and introducing condensed water into the atomizing disk, and the atomizing disk is rotated by the outdoor cooling fan to atomize the water droplets. However, due to the slow fan speed and insufficient centrifugal force, the atomization rate of water droplets is insufficient, so that most of the condensed water still flows out of water droplets. In addition, some manufacturers have proposed to atomize the condensed water by means of ultrasonic atomization, and then contact the atomized molecules on the heat sink to reduce the temperature of the heat sink. However, because of the high energy consumption by ultrasonic atomization, It is economical. In addition, the particle size of the water mist generated by the ultrasonic atomization method is not uniform. When the water mist molecules of the larger particles touch the heat sink, they gradually deposit on the heat sink to generate water, which causes the heat sink to generate metal. Corrosion phenomenon. [New Content] In view of the above-mentioned problems of the prior art, the purpose of the present invention is to provide a cooling system to solve the problem of poor atomization efficiency or easy accumulation of water on the heat sink. = This = the purpose of the proposed cooling system, an atomization device, a water outlet pipe and - heat dissipation components. To the device - produces condensed water and includes - the water tray 1 water tray carrying cold water. The heat dissipating component cools the refrigerating device f to avoid the M373464, and the atomizing device includes an atomizing sheet and a dust chamber. The pressure thunder is divided into the surname and the name is also the coffee. The drive is driven by the 7C piece and the water. The electric drive unit drives the atomization piece to generate vibration, and the water collecting plate and the water tank are connected to deliver the condensed water to the water tank. The chilling device further includes a pumping motor, which is disposed between the water collecting tray and the reading, and (4) the water flowing in the effluent. The Chaosuodu cooling system further includes a fan unit that moves the water mist toward 70 pieces of heat. Wherein, the cooling system further comprises a filter element which is arranged to generate a position between the condensed water and the reading, and the shouting element is used to remove impurities of the condensed water. Among them, the 'filter element has a water tank and a filter cotton, and the water tank stores condensed water. The filter cotton adsorbs impurities of the condensed water in the water tank. Wherein, the cooling system further has a temperature sensing element that detects the temperature of the heat dissipating component to cause the atomizing device to control the amount of atomized water droplets generated. The particle diameter of the medium-sized water droplet is 1 private m to 1 〇〇 y m. The 'atomization device includes a driving circuit', a fixing seat and a water tank. The driving circuit controls the piezoelectric driving element to act. One side of the piezoelectric driving element is fixed to the fixing seat, and the water tank accommodates the condensation. water. The 'atomization device includes a liquid bead delivery tube, and the liquid bead delivery tube transports the condensed water stored in the water tank upward, and forms a curved water film at the nozzle of the liquid bead delivery tube to be adsorbed on One side of the atomized sheet. 5 M373464 wherein the refrigeration device comprises a compressor, a condenser, a valve, an evaporator and a circulation pipeline, and the refrigeration and circulation pipeline is connected to the compressor and the condenser: Guanyi, I, Connected back to the compressor' and the circulating pipe and the heat dissipating component are hot-crossed, the device 're-heat-refrigerant' refrigerant and heat dissipating components
其中,冷媒流通至蒸發器時,冷媒吸取周圍空氣之 熱量而由液態轉變為氣態,使空氣t之水 ⑼ 而生成冷凝水。 π h 其中,霧化片具有複數個微孔。 其中,致冷裝置為一窗型冷氣、一窗型直立式冷氣、 一氣冷分離式冷氣或一箱型水冷式冷氣。 承上所述,因依本創作之冷卻系統,可藉由霧化水 滴冷卻散熱元件以提升致冷裝置之工作效率。此外,因 霧化水滴較小’不易於散熱元件上產生積水而導致金屬 腐蚀0Among them, when the refrigerant flows to the evaporator, the refrigerant absorbs the heat of the surrounding air and changes from the liquid state to the gaseous state, so that the water t (9) generates condensed water. π h wherein the atomized sheet has a plurality of micropores. Among them, the refrigeration device is a window type cold air, a window type vertical cold air, a gas cooled split type cold air or a box type water cooled type cold air. According to the above-mentioned cooling system, the cooling element can be cooled by atomizing water droplets to improve the working efficiency of the refrigeration device. In addition, due to the small amount of atomized water droplets, it is not easy to cause water to accumulate on the heat dissipating components, resulting in metal corrosion.
【實施方式】 以下將參照相關圖式,說明依本創作冷卻裝置之實 施例。 請參閱第2圖及第3圖,其係為本創作之冷卻系統 之方塊圖及第一實施例示意圖。圖中,冷卻系統包含一 致冷裝置11、一霧化裝置12、一出水管路13及一散熱 6 M373464 元件16。 致冷裝置Π可為窗型冷氣、窗型直立式冷氣、氣冷 分離式冷氣或箱型水冷式冷氣,並包括一壓縮機iu: 一凝結器112、一膨脹閥114、一蒸發器115、一循環管 路116(s奮參閱第4圖)、一過濾元件117及一集水盤1^。 其中,循環管路116流通冷卻用冷媒,並連通壓縮機 111、凝結器112、膨脹閥114及蒸發器U5。 散熱元件16由一金屬所製成的散熱鰭片,且散熱元 件16設置於鄰近或接近凝結器112之位置,而可與&結 器112進行熱交換,以降低致冷裝置u之溫度。 。 當致冷裝置11開始運轉時,流通於猶環管路116之 冷媒依序流經壓縮機m、凝結器112、散熱元件16、 膨脹閥114及蒸發器115,再流回壓縮機m,而完成凝 結·蒸發之循環週期。為讓讀者便於了解致冷裝置u之 工作原理,請一併參照第4圖及下述說明。 壓縮機lll(compressor)用以將冷媒由氣態經高壓壓 縮後轉換成位於高壓高溫狀態下之氣體冷煤。接著,當 位於焉溫高壓狀態下之氣體冷煤經過凝結器U2時而 與散熱元件16進行熱交換後,可降低氣體冷媒的溫度及 焓值(enthalpy) ’使氣態冷媒產生相變化轉換為常溫高壓 的液態冷媒。接著,當常溫高壓的液態冷媒通過膨脹閥 114而降壓降溫後’便成為低壓低溫之液態冷媒。接著, 當低壓低溫之液態冷媒通過蒸發器115時,此時冷媒將 及收周圍空氣之熱能而由液態轉變為氣態,導致周圍空 M373464 氣變冷’使周圍空氣中之水氣受冷而凝結成冷凝水3。 當致冷裝置11產生冷凝水3後,可使冷凝水3通過 過濾兀件117,以去除混合於冷凝水3内之雜質。其中, 過滤凡件117設置於以致冷裝置u產生冷凝水3之位 置,且過濾兀件117具有一濾水槽117a及一濾棉117b。 流至濾、水槽117a之冷凝水3可藉由濾棉117b吸附混合 於冷凝水3内之雜質以淨化冷凝水3。完成淨化之冷凝 水3可藉由導管引入集水盤118内。 請續參照第5圖及第6圖,其係為本創作冷卻系統 霧化裝置之第一示意圖及第二示意圖。霧化裝置12可設 置於散熱元件16之下方,並包括一霧化片121、一壓電 驅動兀件122、一水槽123、一驅動電路124、一固定座 125及一液珠輸送管126。 壓電驅動元件122可為石英或陶瓷材質所製成,其 可為一平板體,且壓電驅動元件之一端可固設於固定座 125内。驅動電路丨24用以控制壓電驅動元件122作動。 其中’壓電驅動元件122之工作原理是藉由供應一交流 電於設置於壓電驅動元件122兩侧之導電層(圖未示), 使壓電驅動元件122因交流電電場週期性反覆變化,造 成導電層電場變化而反覆擴張收縮,藉以產生振動。 霧化片121則可夾持於壓電驅動元件122之一側, 並具有複數個微孔121a,其孔徑可介於lem至100"m 之間,且霧化片121可藉由壓電驅動元件122之帶動而 振動。水槽123則設置於霧化片121之一側。 M373464 出水管路13則連通集水盤118及水槽123,用以將 ,存於集水盤118之冷凝水3導入水槽123中。液珠輸 送官126可將儲存於水槽123内之冷凝水3往上輸送, 並可於管口處形成一曲面水膜而吸附於霧化片12丨之一 侧。其中,冷凝水3可藉由虹吸原理由集水盤118流至 -水槽123内,或於致冷裝置U内設置一抽水馬達 •抽水馬達119可設在集水盤118及水槽123間藉由抽水 馬達119抽取冷凝水3,以將冷凝水3導入至水槽123 零内。 曰 當通電至壓電驅動元件122時,壓電驅動元件 則因壓電效應(PieZ0effect)而將電能轉變為機械振動 能,並帶動霧化片121振動。藉由液珠輸送管126持續 =儲存於水槽内之冷凝水3往霧化片121之方向輸送' 當霧化片121振動時,便可藉由霧化片121之微孔ΐ2ι& 使冷凝水3轉變成霧化水滴4 ^當霧化水滴4產生後, •-可藉由自然對流之方式往上擴散而朝散熱元件16之方 向移動。當霧化水滴4接觸散熱元件16時,便吸收散熱 兀件16之熱能而蒸發,藉以降低散熱元件16之溫度, 如第2圖所示。由於霧化片121上之微孔可控制霧化水 滴之顆粒直彳工’使霧化水滴4之顆粒直徑對應微孔12 ^ & 孔t且尺寸約為1 # m至1〇〇β m之間因此不易於散 熱元件16上產生積水狀態,造成散熱元件“受潮而腐 蝕。此外,當儲存於水槽123内冷凝水3之水位過高時, 可以自動方式或手動方式關閉抽水馬達119,或設置一 M373464 止水閥(圖未示)於出水管路13,以停止冷凝水3繼續由 集水盤118導入於水槽123内,可避免儲存於水槽123 内之冷凝水3過多而溢出,進而滴漏至外界。 此外,冷卻系統更包含一溫度感測元件15,其設置 於散熱元件16之周圍,可用以感應散熱元件16之溫度。 冨散熱元件16溫度過南時’霧化裝置12可據以提升霧 化水滴4之產生量,以避免壓縮機ill散熱不足,造成 跳機。 請參閱第7圖,其係為本創作冷卻系統之第二實施 例之示意圖。在本實施例中,致冷裝置n、霧化裝置12、 散熱元件16、及出水管路13之結構與功能與第一實施 例相同,在此不再贅述。本實施例與第一實施例之差異 在於霧化裝置12之一侧更設置一風扇裝置14,並使霧 化裝置12係設置於散熱元件16之侧邊,而使霧化裝置 12設置於風扇裝置14之間。當霧化裝置12產生霧化水 滴4時,可藉由風扇裝置14帶動周圍空氣流動,以強制 對流之方式帶動霧化水滴4朝散熱元件16之方向移動, 亦可達成降低散熱元件16溫度之功效。在此實施例中, 風扇裝置14可被安裝在致冷裝置11内或外,只要是強 =對流的方式帶動霧化水滴4朝散熱元件16的方向移動 ,皆屬本新型專利所述之風扇裝置。 例凊f閱第8圖,其係為本創作冷卻系統之第三實施 鸯^不忍圖。在本實施例中,致冷裝置1卜霧化裝置12, ·、、、几件16及出水管路13之結構與功能與第一實施例 M373464 相同’在此不再贅述。本實施例與第—實施例之差異在 於霧化裝置是設置於集水盤118上方,當水槽123所 承载之冷凝水3過多而溢出時,溢滿出來之冷凝水3可 ^回流至集水盤118内’不但可重複循環使用,亦可避 免溢滿出來之冷凝水3滴漏至外界。[Embodiment] Hereinafter, an embodiment of a cooling device according to the present invention will be described with reference to the related drawings. Please refer to FIG. 2 and FIG. 3, which are block diagrams of the cooling system of the present invention and a schematic view of the first embodiment. In the figure, the cooling system comprises a refrigeration unit 11, an atomizing unit 12, a water outlet line 13 and a heat dissipating 6 M373464 element 16. The refrigeration device can be a window type cold air, a window type vertical cold air, an air cooled split type cold air or a box type water cooled type cold air, and includes a compressor iu: a condenser 112, an expansion valve 114, an evaporator 115, A circulation line 116 (see Fig. 4), a filter element 117 and a water collection tray 1^. Among them, the circulation line 116 flows through the cooling refrigerant, and communicates with the compressor 111, the condenser 112, the expansion valve 114, and the evaporator U5. The heat dissipating member 16 is made of a metal fin and the heat dissipating member 16 is disposed adjacent to or near the condenser 112 to exchange heat with the & . When the refrigeration device 11 starts to operate, the refrigerant flowing through the helium loop 116 flows through the compressor m, the condenser 112, the heat dissipating member 16, the expansion valve 114, and the evaporator 115, and then flows back to the compressor m. Complete the cycle of condensation and evaporation. In order to make it easier for the reader to understand the working principle of the cooling device u, please refer to Figure 4 and the following description. The compressor lll (compressor) is used to convert the refrigerant from a gaseous state to a gas cold coal under a high pressure and high temperature state by high pressure compression. Then, when the cold coal in the high temperature state of the helium temperature passes through the condenser U2 and exchanges heat with the heat dissipating component 16, the temperature and the enthalpy of the gas refrigerant can be lowered to convert the phase change of the gaseous refrigerant to the normal temperature. High pressure liquid refrigerant. Then, when the liquid refrigerant of normal temperature and high pressure is lowered and lowered by the expansion valve 114, it becomes a liquid refrigerant of low pressure and low temperature. Then, when the low-pressure low-temperature liquid refrigerant passes through the evaporator 115, the refrigerant will change the heat energy of the surrounding air and change from the liquid state to the gaseous state, causing the surrounding air M373464 gas to cool, so that the water in the surrounding air is cooled and condensed. Condensed water 3. When the chilling device 11 generates the condensed water 3, the condensed water 3 can be passed through the filtering element 117 to remove the impurities mixed in the condensed water 3. The filter member 117 is disposed at a position where the condensing water 3 is generated by the refrigerant device u, and the filter element 117 has a filter tank 117a and a filter 117b. The condensed water 3 flowing to the filtration and water tank 117a can adsorb the impurities mixed in the condensed water 3 by the filter cotton 117b to purify the condensed water 3. The condensed water 3 which has been purified can be introduced into the water collecting tray 118 by means of a conduit. Please refer to FIG. 5 and FIG. 6 respectively, which is the first schematic diagram and the second schematic diagram of the atomization device of the cooling system. The atomizing device 12 can be disposed under the heat dissipating component 16, and includes an atomizing sheet 121, a piezoelectric driving element 122, a water tank 123, a driving circuit 124, a fixing base 125 and a liquid bead conveying tube 126. The piezoelectric driving element 122 can be made of quartz or ceramic material, and can be a flat body, and one end of the piezoelectric driving element can be fixed in the fixing base 125. The driving circuit 丨 24 is used to control the piezoelectric driving element 122 to operate. The working principle of the piezoelectric driving element 122 is that the piezoelectric driving element 122 periodically changes repeatedly due to the alternating electric field by supplying an alternating current to a conductive layer (not shown) disposed on both sides of the piezoelectric driving element 122. The electric field of the conductive layer changes and expands and contracts repeatedly, thereby generating vibration. The atomizing sheet 121 can be clamped on one side of the piezoelectric driving element 122 and has a plurality of micro holes 121a, the aperture of which can be between lem and 100"m, and the atomizing sheet 121 can be driven by piezoelectric The element 122 is driven to vibrate. The water tank 123 is disposed on one side of the atomizing sheet 121. The water outlet pipe 13 of the M373464 is connected to the water collecting tray 118 and the water tank 123 for introducing the condensed water 3 stored in the water collecting tray 118 into the water tank 123. The liquid droplet transporting unit 126 can transport the condensed water 3 stored in the water tank 123 upward, and can form a curved water film at the nozzle to be adsorbed on one side of the atomizing sheet 12 . The condensed water 3 can flow from the water collecting tray 118 to the water tank 123 by the siphon principle, or a pumping motor can be disposed in the cooling device U. The pumping motor 119 can be disposed between the water collecting tray 118 and the water tank 123 by the pumping motor. The condensed water 3 is withdrawn 119 to introduce the condensed water 3 into the sink 123.曰 When energized to the piezoelectric driving element 122, the piezoelectric driving element converts electrical energy into mechanical vibration energy due to the piezoelectric effect (PieZ0effect), and drives the atomizing sheet 121 to vibrate. By the liquid bead delivery tube 126, the condensed water 3 stored in the water tank is continuously conveyed in the direction of the atomizing sheet 121. When the atomizing sheet 121 vibrates, the condensed water can be made by the micropores 雾化2ι& 3 is converted into atomized water droplets 4 ^ When the atomized water droplets 4 are generated, - can be diffused upward by natural convection to move toward the heat dissipating member 16. When the atomized water droplets 4 contact the heat dissipating member 16, the heat of the heat dissipating member 16 is absorbed to evaporate, thereby lowering the temperature of the heat dissipating member 16, as shown in Fig. 2. Since the micropores on the atomizing sheet 121 can control the particles of the atomized water droplets directly, the particle diameter of the atomized water droplets 4 corresponds to the micropores 12 ^ & the holes t and the size is about 1 # m to 1 〇〇β m Therefore, it is not easy to generate a water accumulation state on the heat dissipating member 16, causing the heat dissipating member to be "moistened and corroded. Further, when the water level of the condensed water 3 stored in the water tank 123 is too high, the pumping motor 119 can be automatically or manually turned off, or A M373464 water stop valve (not shown) is disposed in the water outlet pipe 13 to stop the condensed water 3 from being continuously introduced into the water tank 123 by the water collecting tray 118, thereby preventing the condensed water 3 stored in the water tank 123 from overflowing and overflowing. In addition, the cooling system further includes a temperature sensing component 15 disposed around the heat dissipating component 16 to sense the temperature of the heat dissipating component 16. 冨 When the temperature of the heat dissipating component 16 is too south, the atomizing device 12 can The amount of atomized water droplets 4 is increased to avoid insufficient heat dissipation of the compressor ill, resulting in a trip. Please refer to Fig. 7, which is a schematic diagram of a second embodiment of the present invention. In this embodiment, the cooling is performed. Loading The structure and function of the atomizing device 12, the heat dissipating component 16, and the water outlet pipe 13 are the same as those of the first embodiment, and are not described herein again. The difference between this embodiment and the first embodiment is that one of the atomizing devices 12 A fan device 14 is further disposed on the side, and the atomizing device 12 is disposed on the side of the heat dissipating component 16, and the atomizing device 12 is disposed between the fan device 14. When the atomizing device 12 generates the atomized water droplets 4, The fan device 14 can be used to drive the surrounding air to force the convection to move the atomized water droplets 4 toward the heat dissipating component 16 , thereby reducing the temperature of the heat dissipating component 16 . In this embodiment, the fan device 14 can be It is installed in or outside the cooling device 11, and as long as it is strong=convection, the atomized water droplets 4 are moved in the direction of the heat dissipating member 16, which are the fan devices described in the present patent. It is the third implementation of the creative cooling system. In the present embodiment, the structure and function of the cooling device 1 and the atomizing device 12, ·,, several pieces 16 and the water outlet pipe 13 An embodiment M373464 is the same 'not here The difference between the present embodiment and the first embodiment is that the atomizing device is disposed above the water collecting tray 118. When the condensed water 3 carried by the water tank 123 overflows too much, the condensed water 3 overflowing can be returned to The water collecting tray 118 can be recycled not only repeatedly, but also can prevent the overflowing condensed water 3 from leaking to the outside.
綜上㈣’本廳冷卻线,其魏在於藉由設置 霧^裳置產生水霧,崎溫散熱元件,藉崎低壓縮機 工作溫度,並提升冷卻系統之工作效率。 本創作冷卻系統之另一功效在冑由壓電驅動元件帶 動霧化片震動以產生霧化水滴,可較傳 超音波方式更可節省能源。 ^作冷卻系狀再—功效在於所產生的霧化水滴 2直徑較小,不易在散熱元件上產生積水狀態造成 金屬腐姓情形。 本創作冷㈣統之又—功效在於可設置—偵測散執 ^牛溫度之溫度感測树,可依據散熱it件之溫度高; 調整霧化水滴之產生量,以避免壓職壓縮不足而造 成跳機。 以上所述僅為舉例性,而非為限制性者。任何 :本創作之精神與料,而對其進行之#效修改或變 更,均應包含於後附之申請專利範圍中。 MJ73464 【圖式簡單說明j 第1圓係為習知技藝冷氣機之排水裝置示音圖. 第2圖係為本創作冷卻系統之方塊圖; 第3圖係為本創作冷卻系統第一實施例示意圖; 第4圖係為本創作冷卻系統冷媒循環示意圖; 第5圖係、為本創作冷卻系統霧化裝置第一示意圖; 第6圖係、為本創作冷卻系統霧化裝置第二示意圖; 第7圖係為本創作冷卻系統第二實施例示意圖;及 第8圖係為本創作冷卻系統第三實施例示意圖。 【主要元件符號說明】 20 :冷氣機; 21:出水口; 30 :過濾器; 40 =排水器; 41 :抽水馬達; 42 :出水管; II :致冷裝置; III :壓縮機; 112 :凝結器; 114 :膨脹閥; 115:蒸發器; 12 M373464 116 :循環管路; 117 :過濾元件; 117a :濾水槽; 117b :濾棉; 118 :集水盤; 119 :抽水馬達; 12 :霧化裝置; 121 :霧化片; 121a:微孔; 122 :壓電驅動元件; 123 :水槽; 124 :驅動電路; 125 :固定座; 126 :液珠輸送管; 13 :出水管路; 14 :風扇裝置; 15 :溫度感測元件; 16 :散熱元件; 3 :冷凝水;及 4:霧化水滴。 13In summary (4) 'the cooling line of the main hall, the Wei is to create a water mist by setting the fog, the heat sinking element, the low compressor operating temperature, and improve the working efficiency of the cooling system. Another effect of the present cooling system is that the piezoelectric driving element drives the atomizing sheet to vibrate to generate atomized water droplets, which can save energy by transmitting the ultrasonic method. ^As a cooling system, the effect is that the atomized water droplets 2 produced are small in diameter, and it is difficult to cause water accumulation on the heat dissipating components to cause metal rot. The creation of the cold (four) unified - the effect is that it can be set - the temperature sensing tree that detects the temperature of the loose ^ cow temperature, can be based on the temperature of the heat sinking parts; adjust the amount of atomized water droplets to avoid insufficient compression of the job Caused a jump. The above is intended to be illustrative only and not limiting. Any: The spirit and material of this creation, and the modifications or changes made to it shall be included in the scope of the patent application attached. MJ73464 [Simple diagram of the diagram j The first circle is the sound diagram of the drainage device of the conventional air conditioner. The second diagram is the block diagram of the creation cooling system; the third diagram is the first embodiment of the creation cooling system. Schematic diagram; Figure 4 is a schematic diagram of the refrigerant circulation of the cooling system; Figure 5 is the first schematic diagram of the atomization device of the cooling system; Figure 6 is the second schematic diagram of the atomization device of the creation cooling system; 7 is a schematic view of a second embodiment of the creation cooling system; and FIG. 8 is a schematic view of a third embodiment of the creation cooling system. [Main component symbol description] 20: air conditioner; 21: water outlet; 30: filter; 40 = drainer; 41: pumping motor; 42: outlet pipe; II: refrigeration device; III: compressor; 112: condensation 114: expansion valve; 115: evaporator; 12 M373464 116: circulation line; 117: filter element; 117a: water tank; 117b: filter cotton; 118: water collecting tray; 119: pumping motor; 12: atomizing device 121: atomizing sheet; 121a: microhole; 122: piezoelectric driving element; 123: sink; 124: driving circuit; 125: fixing seat; 126: liquid bead conveying pipe; 13: water outlet pipe; 15 : temperature sensing element; 16 : heat dissipating element; 3 : condensed water; and 4: atomized water droplets. 13