M269419 八、新型說明: 【新型所屬之技術領域】 除M269419 8. Description of new model: [Technical field to which new model belongs] Except
本創作係與除濕機有關,特別是有_ 機除濕穩定性及其效率之巢置。 一種用以提升 5【先前技術】 請參閱第四圖,就習知技藝所知,一般除濕 循環系統(⑽),其冷凝器(曝並列設於其蒸發華^後 方,使得經蒸發器(82)降溫後之乾冷空氣可先通過冷凝哭 降並在降低冷凝摩)内冷媒溫度後,再排出除^ 10外’以避免冷媒在進入膨脹閥(83)時能完全液態,而影響蒸 發器(82)除濕效果。而實際上,冷象循環系統㈣之性能常 會隨著環境溫度增高而降低,換言之,當周遭環境溫度愈 高時,冷凝器(81)之散熱性即相對差,僅藉由通過冷凝器(81) 之乾冷空氣並無法完全將冷媒溫度降低,導致進入蒸發器 (82)之冷媒溫度隨之升高,蒸發器(82)因而無法有效地將空 氣中之水分液化,如此不斷惡性循環下,不僅影響除濕機 的除濕性能,也降低除濕機之使用壽命。 有鑑於此,如何提升蒸發器之效能,始是此一領域極 大課題。習知方式中有對冷凝器灑水、浸水以及將冷凝器 20尺寸加大三種方式,來增加冷凝器出口端的冷媒過冷度。 然而’前二者執行困難度高,後者必需同時考慮到除濕機 之散熱風扇是否可提供足以通過冷凝器整體之風量,否則 依然無法有效降低進入蒸發器之冷媒溫度,並使除濕機之 製作成本大幅提昇。 M269419 【新型内容】 2創作之主要目的在提供—種提升除濕機除濕 裝置^保常溫時,進人蒸發器人口端之冷媒為 5最佳/里度,使侍療發器除濕效率因而提升;並在外界高溫 時,減少未液化冷媒比例,進一步穩定蒸發器之作業效γ 緣是,為達成前揭目的,本創作係提供一種提升除濕 機除濕的穩定和效率之裝置,該除濕機包含有以一迴路前 10後相連結之一壓縮機、一冷凝器'一膨脹閥以及一蒸發器, =該冷凝器後方並設有一散熱風扇排風,使得通過該蒸發 =之乾冷工氣經過该冷凝器之身部;而該裝置設在乾冷空 氣通過路徑上,位於該冷凝器以及該蒸發器之間,其並呈 官狀兩端與該冷凝器以及該蒸發器間之迴路連通,用以供 15冷媒通過與乾冷空氣進行熱交換。 【實施方式】 為更詳細地說明本創作之結構,茲舉一較佳實施例並 配合圖式,說明如下,其中: 第一圖係本創作一較佳實施例之組合於一除濕機冷凍 循環系統之正視示意圖。 第二圖係本創作一較佳實施例之組合於一除濕機冷束 循環系統之側視示意圖。 第三圖係本創作一較佳實施例之組合於一除濕機冷凍 M269419 循環系統之結構示意圖。 第四圖係習用除濕機冷凍循環系統之示意圖。 首先參閱第一至三圖,為本創作一較佳實施例『提升 5除濕機除濕的穩定和效率之裝置』,圖中代表符號為10,而 該除濕機(圖中未示)包含有一壓縮機(2〇)、一冷凝器(3〇)、 一膨脹閥(40)以及一蒸發器(50),且該壓縮機(2〇)、該冷凝 器(30)、該膨脹閥(40)以及該蒸發器(50)間以一迴路(6〇)前後 連結,該迴路(60)中並流通有循環冷媒,另外,該除濕機於 ίο 6亥冷凝益(30)後方具有一散熱風扇(70),用以將外界空氣抽 送入該除濕機中,空氣在通過該蒸發器(50)時,其内含所有 的水氣會於該蒸發器(50)表面凝固呈露珠滴落,因而生成乾 冷空氣達到除濕之效果。由於該除濕機之壓縮機(2〇)、冷凝 器(30)、膨脹閥(40)以及蒸發器(50)所形成之系統及其循環 I5 係為習知技藝,於此容不贅述。 該裝置(10)於本實施例中係為一管體,其内具有一通道 (圖中未示),兩端分別接設於該冷凝器(3〇)及該膨脹閥(4〇) 間之迴路(60)上,而可供該迴路(60)中之冷媒流入,且該裝 置(10)身部延伸於該冷凝器(3〇)以及該膨脹閥(4〇)間乾冷空 20氣通過之路徑上,而能與乾冷空氣進行熱交換,使得流入 5亥裝置(10)中之冷媒過冷度提升。 換言之,冷媒在通過該裝置(10)後,其溫度將更進一步 降低’確保進入該膨脹閥(40)前的冷媒為完全液態,藉此使 得進入該蒸發器(5 0)入口端之冷媒溫度為最佳狀態,該蒸發 M269419 而 田 率 器(5〇)因而可充分發揮其功能,增加其對空氣之除濕率,· 其所生成之乾冷空氣再接續移除該裝置(10)中之冷媒L ^ ’隨後’乾冷空氣經過該冷凝器(30)時,再被該冷凝器^ ϋ溫’如此—來形成週而復始之循環。另外,根據創作人 貫驗結果’除顯·環境溫度提料,由於本創作之裝 置(10)可再次降低蒸發器(5〇)入口端之冷媒溫度因此可 以減夕未液化冷媒比例H穩定蒸發器⑽之作業效 藉由上述結構,本創作與習知技藝相較,本創作至少 具有以下之優點; L提高了除濕機的除濕穩定度。 2·使得蒸發器除濕效率提升。 3·其製作成本低,且使用壽命更長。 此外,補充說明的是,本創作主要目的在利用 irt乾冷空氣可通過雜上’自然地形賴環而降低^ 、二=,因此並不限制該裝置形式,若該裝置能沿其管身 佈认夕數則,將可對流過該裝置之冷媒相更佳效 果0 8 20 M269419 【圖式簡單說明】 第一圖係本創作一較佳實施例之組合於一除濕機冷束 循環系統之正視示意圖。 第二圖係本創作一較佳實施例之組合於一除濕機冷凍 5 循環系統之側視示意圖。 第三圖係本創作一較佳實施例之組合於一除濕機冷凍 循環系統之示意圖。 第四圖係習用除濕機冷凍循環系統之示意圖。 10【主要元件符號說明】 裝置(10) 壓縮機(20) 冷凝器(30) 膨脹閥(40) 蒸發器(50) 迴路(60) 散熱風扇(70) 15習用 冷凍循環系統(80) 冷凝器(81) 蒸發器(82) 膨脹閥(83)This creation is related to the dehumidifier, especially the nest with dehumidification stability and efficiency. A kind of lifting device 5 [Prior art] Please refer to the fourth figure. As far as the conventional art is known, the general dehumidification cycle system (⑽), the condenser (exposed in parallel is arranged behind its evaporation Hua ^, so that the evaporator (82 ) After cooling, the dry and cold air can be cooled down through condensation and lower the condensing friction.) After the temperature of the refrigerant is discharged, it is discharged except ^ 10 'to avoid that the refrigerant can be completely liquid when it enters the expansion valve (83) and affect the evaporator ( 82) Dehumidifying effect. In fact, the performance of the cold image circulation system 常 often decreases as the ambient temperature increases. In other words, when the ambient temperature is higher, the heat dissipation of the condenser (81) is relatively poor, and only by passing through the condenser (81 Dry cold air cannot completely reduce the temperature of the refrigerant, which causes the temperature of the refrigerant entering the evaporator (82) to rise accordingly, and the evaporator (82) cannot effectively liquefy the moisture in the air. In this continuous vicious cycle, not only Affects the dehumidification performance of the dehumidifier, and also reduces the service life of the dehumidifier. In view of this, how to improve the efficiency of the evaporator has been a great subject in this field. The conventional methods include three methods of spraying and immersing the condenser with water and increasing the size of the condenser 20 to increase the degree of subcooling of the refrigerant at the outlet end of the condenser. However, the first two are difficult to implement, and the latter must also consider whether the cooling fan of the dehumidifier can provide enough air volume to pass through the entire condenser. Otherwise, the temperature of the refrigerant entering the evaporator cannot be effectively reduced, and the production cost of the dehumidifier cannot be effectively reduced. Greatly improved. M269419 [New content] 2 The main purpose of the creation is to provide a type of dehumidifier to enhance the dehumidifier ^ At room temperature, the refrigerant entering the evaporator population side is 5 best / mile, so that the dehumidification efficiency of the hair dryer is improved; And when the outside temperature is high, it reduces the proportion of unliquefied refrigerant and further stabilizes the operating efficiency of the evaporator. Γ For the purpose of achieving the previous disclosure, this creation is to provide a device to improve the stability and efficiency of dehumidifier dehumidifier. The dehumidifier contains A compressor, a condenser, an expansion valve, and an evaporator are connected to the front and back of the primary circuit. A cooling fan exhaust is provided behind the condenser, so that the dry and cold working gas passing through the evaporation passes through the condensation. The device is located on the path of dry and cold air between the condenser and the evaporator, and the two ends of the device are in official communication with the circuit between the condenser and the evaporator. 15 Refrigerant exchanges heat with dry cold air. [Embodiment] In order to explain the structure of this creation in more detail, a preferred embodiment will be described in conjunction with the drawings, which are described below, where: The first figure is a combination of a preferred embodiment of this creation in a dehumidifier refrigeration cycle Front view of the system. The second figure is a schematic side view of a combination of a preferred embodiment of the present invention in a cold beam circulation system of a dehumidifier. The third diagram is a schematic diagram of the structure of a circulation system of the M269419 refrigerating and freezing system combined with a preferred embodiment of the present invention. The fourth diagram is a schematic diagram of a refrigeration cycle system of a conventional dehumidifier. First refer to the first to third drawings, which is a preferred embodiment of the invention "device for improving the stability and efficiency of 5 dehumidifier dehumidifiers". The representative symbol in the figure is 10, and the dehumidifier (not shown) contains a compression A compressor (20), a condenser (30), an expansion valve (40), and an evaporator (50), and the compressor (20), the condenser (30), and the expansion valve (40) And the evaporator (50) is connected back and forth with a circuit (60), and a circulating refrigerant is circulated in the circuit (60). In addition, the dehumidifier is provided with a cooling fan (30) behind the condenser (30). 70), which is used to pump external air into the dehumidifier. When the air passes through the evaporator (50), all the water and gas contained in it will solidify on the surface of the evaporator (50) and form dew drops, thus generating Dry and cold air achieves the effect of dehumidification. Since the system formed by the compressor (20), the condenser (30), the expansion valve (40), and the evaporator (50) of the dehumidifier and its circulation I5 are conventional techniques, they will not be repeated here. The device (10) is a tube body in this embodiment, which has a channel (not shown), and the two ends are respectively connected between the condenser (30) and the expansion valve (40). The circuit (60), and the refrigerant in the circuit (60) can flow in, and the body of the device (10) extends between the condenser (3) and the expansion valve (4) dry and cold air 20 gas Through the path, it can exchange heat with dry cold air, so that the degree of subcooling of the refrigerant flowing into the device (10) can be improved. In other words, after the refrigerant passes through the device (10), its temperature will be further reduced. 'Ensure that the refrigerant before entering the expansion valve (40) is completely liquid, thereby making the temperature of the refrigerant entering the inlet of the evaporator (50). In the best condition, the evaporation M269419 and the field rate device (50) can fully perform its function, increase its dehumidification rate to the air, and the dry cold air generated by it will then remove the refrigerant in the device (10). L ^ 'Then, when the dry cold air passes through the condenser (30), it is used by the condenser ^ ϋ' to form a cycle of cycles. In addition, according to the results of the creator ’s inspection, 'In addition to the display and ambient temperature, the device (10) of this creation can reduce the refrigerant temperature at the inlet of the evaporator (50) again, so that the proportion of the unliquefied refrigerant H can be stably evaporated With the above structure, compared with the known techniques, this creation has at least the following advantages; L improves the dehumidification stability of the dehumidifier. 2. Make the dehumidification efficiency of the evaporator improved. 3. It has low production cost and longer service life. In addition, it is added that the main purpose of this creation is to use irt dry and cold air to reduce ^ and II = by adding the natural terrain, so it does not limit the form of the device. If the device can be recognized along its body Evening numbers, better effect can be achieved on the refrigerant phase flowing through the device. 0 8 20 M269419 [Simplified diagram] The first picture is a schematic front view of a combination of a preferred embodiment of this invention and a cold beam circulation system of a dehumidifier. . The second figure is a schematic side view of a combination of a preferred embodiment of the present invention and a refrigeration 5 cycle system of a dehumidifier. The third diagram is a schematic diagram of a refrigeration cycle system of a dehumidifier combined with a preferred embodiment of the present invention. The fourth diagram is a schematic diagram of a refrigeration cycle system of a conventional dehumidifier. 10 [Description of main component symbols] Device (10) Compressor (20) Condenser (30) Expansion valve (40) Evaporator (50) Circuit (60) Cooling fan (70) 15 Conventional refrigeration cycle system (80) Condenser (81) Evaporator (82) Expansion valve (83)