201211480 六、發明說明: 【發明所屬之技術領域】 本發明的實施方式涉及一種冰箱。 【先前技術】 近年來,在家用冰箱中,眾所周知有一種例如設置利 用靜電霧化來產生霧的霧產生裝置(除菌成分產生機構), 並將由該霧產生裝置所產生的霧供給至冷藏室等的儲藏室 的冰箱。此時,在由霧產生裝置所產生的霧中,包含具有 ,氧化作用的羥自由基(hydr0Xyi radicai)或臭氡(〇z〇ne ) 等的除菌成分,因此能夠期待霧的供給目標的除菌 [先前技術文獻] ' '' [專利文獻] [專利文獻1]曰本專利特開2006_57999號公 [專利文獻2]曰本專利第4052353號公報a 在家用冰箱中,有的1借^; i奋人 該微魚的 因此,提供一種可實現微康室的除 而且,如果要利用通過冷卻器的一^的冰箱 產生裝置(除菌成分產生機構)放c來將從 室的多個儲藏室,職菜室有可能會‘二至包含韻 因此,提供_種冰箱,在將從霧產生裝;。 產生機構)放出的霧供給至:置(除菌成 箱中,能夠防止蔬菜室過冷。a 、多個儲藏室的 6 201211480 且古實施方式的冰箱,其特徵在於包括:冰箱本體, 二、1;.、至;冷卻器,設在該冰箱本體中,用於冷卻所述 至’送風機’使所述微;東室的空氣接觸所述冷卻器並 二ϋ以及除菌成分產生機構’產生除菌成分’且採用下 二二1即,將所述除菌成分產生機構配置於所述微凍室 .將由该除菌成分產生機構產生的除菌成分供給至 所述微凍室。 據此’可容易地實現儲藏肉或魚等的微柬室的除菌或 除臭。 為讓本發明之上述和其他目的、特徵和優點能更明顯 ,下文特舉較佳實施例,並配合所附圖式,作詳細說 明如下。 【實施方式】 箱)。以下,參照附圖來說明多個實施方式的冰箱(冷凍冰 二+严外’在各實施方式中,對於實質上相同的構成部位 ‘注相同的符號,並省略說明。 (第1實施方式) 以首先,參照圖1〜圖11來說明第1實施方式。如圖1 Q 2所示,冰相本體1是在前表面開口的縱長矩形箱 成的隔熱箱體2内,沿上下方向排列設置多個儲藏室而構 室具體而言,在隔熱箱體2内,從上段起依序設有冷藏 =3、蔬菜室4,在其下方,左右排列設有製冰室5和小Α 凍室6,在他們的下方設有冷凍室7。 7 201211480 水至5内,設有眾所周知的自動製冰裝置8 (參 血入忐娃+ ,隔熱相體2基本上是在鋼板制的外箱2a ,、I:!!制的内箱2b之間設置隔熱材料2c而構成。 藏室I及,^以及蔬菜室4均為冷藏溫度段的儲藏室,冷 而:下八,菜室4之間通過塑料(plastic)製的分隔壁10 I隔。通常,冷藏室3的維持溫度設為rC〜5°C, 1 維持溫度設為比其稍高的2°C〜6C。 阻劫藏至3的前表面部,設有鉸鏈(hinSe)開閉式的 1¾ 熱門 3a,名:$矣 $ —1 j ^ . 在隔鼽鬥 _L采至4的刖表面’設有抽出式的隔熱門4a。 在DΓ、人4a的背面部,連結著構成儲藏容器的下部盒u。 下的上部,設有比下部盒11小型的上部盒12。 冷藏至3内通過多個搁板13而上下分隔成多段。如圖 =,在冷藏室3内的最下部(分隔壁1〇的上部), 右侧;又有微陳(chilled)冑14,在其左侧,上下設有蛋盒 15以及小物盒16,進而,在他們的左侧設 (tank)17。 相 儲水箱17是用於儲存供給至自動製冰裝置8的製冰盒 8a的水,且可由用戶(user)裝卸地設置。 在微凍室14内,可出入地設有微凍盒18 (相當於容 器)。從微凍室14的上部到設置儲水箱17的部分的上部而 設有載置板70。 ° 如圖9所示,在微凍室14與蛋盒15以及小物盒16 的設置部之間設有分隔板71a,而且,在蛋盒15以及物 盒16的設置部與儲水箱17的設置部之間也設有分隔板 8 201211480 71b。 a載置板70構成微凍室14的頂板部,微凍室14的上部 由載置板7Q所封閉。微;東室14的前表面由收納狀態的 微珠盒18的前表面壁18a所封閉。 微凍至14的維持溫度較上部的冷藏室3以及下部的蔬 菜至4稍低,例如設為〇O〜rc。微凍室14與下方的 菜室4經由分隔壁10而上下鄰接。 如圖1以及圖10所示,在微凍盒18的後上部,具體 而了’在自前方觀察時從微凍盒18的左右側壁的後上到 後β壁的上部’以比前表面壁18a以及左右側壁的前部更 低的方式而形成有切口部18b。 製冰室5、小冷凍室6與冷凍室7均為冷凍溫度段(例 —18 C左右)的儲藏室’蔬菜室4與製冰室5以及小冷;東 室6之間通過隔熱分隔壁19而上下分隔。 兮製水室5的前表面部,設有抽出式的隔熱門5a,在 k =熱門5a的背面部連結著儲冰容器2〇。在小冷凍室6 部,雖未圖示’但也設有連結著儲藏容器的抽出 i、門。在冷康室7的前表面部,也設有連結著儲藏 办益22的抽出式的隔熱門7ae A凌^水相本體1中,組裝有具備冷制冷卻器24以及 ί卻器25 $ 2個冷卻器的冷賴環(⑽),所述 二蔬菜24用於對冷藏溫度段賴藏室即冷藏室3 用於對于冷卻,所述冷相冷卻器% 東/皿度段的儲臧室即所述製冰室5、小冷凍室ό 201211480 以及冷凍室7進行冷卻。 在冰箱本體1的下端部背面侧’設有機械室26,在該 機械室26内,配設有構成冷凍循環的壓縮機27及冷凝器 等,並且配設有用於對他們進行冷卻的冷卻風扇(fan)或 除霜水蒸發孤28等。 在冰箱本體1的背面靠下部部分,設有安震著控制整 體的微電腦(micro computer)等的控制裝置29。冷藏用 冷卻器24及冷;東用冷卻器25經由與這些冷卻器24、25 一同構成冷珠循環的壓縮機27等而間接地電性連接於外 箱2a。 在冰箱本體1内的冷束室7的背部,設有冷康用冷卻 器室30。在該冷凍用冷卻器室30内,位於下部而配^有 所述冷陳用冷卻器25或除霜用加熱器(heater )(未圖示) 等’並且位於上部而配設有冷凍用送風風扇31。在冷束用 冷卻器室30的前表面的中間部,設有冷氣吹出口 3〇a,在 下端部設有返回口 30b。 在該構成中,當驅動冷凍用送風風扇31時,由冷來用 冷卻器25所生成的冷氣進行從所述冷氣吹出口 3〇a供給至 製冰至5、小冷〉東室6、冷;東至7内,然後再從返回口 3〇匕 返回冷;東用冷卻器室3〇内的循環。 通過該冷氣,製冰室5、小冷凍室6以及冷凍室7得 以冷卻。另外,在冷凍用冷卻器25的下方部,設有承接冷 凍用冷卻器25的除霜時的除霜水的排水管32。該排水管 32所承接的除霜水被導至冰箱外的機械室26内所設的除 201211480 霜水蒸發皿28並蒸發。 並且,在冰箱本體1内的冷藏室3以及蔬菜室4的背 部,以下述方式而配設有冷藏用冷卻器24、或用於將由該 冷藏用冷卻器24生成的冷氣供給至所述冷藏室3 (及蔬菜 室4)内的冷氣導管34、用於使所述冷氣循環的冷藏用送 風機35等。 即,在冰箱本體1中的冷藏室3的最下段的後方(微 凍室14的後方)’設有構成冷氣導管34的一部分的冷藏用 冷卻器室36,在該冷藏用冷卻器室36内配設有冷藏用冷 卻器24。 在冷藏用冷卻器室36的上方’設有向上方延伸的冷氣 供給導管37 ’冷滅用冷卻器室36的上端部連通於冷氣供 給導管37的下端部。此時,由冷藏用冷卻器室36和冷氣 供給導管37構成冷氣導管34。 7 冷藏用冷卻器室36的前部壁36a向冷氣供給導管37 更前方突出。而且’在該前部壁36a的背侧,設有具有隔 熱性的隔熱材料38。在冷氣供給導管37的前部,^有多 個向冷藏室3内開口的冷氣供給口 39。 在冷藏用冷部盗室36内的下部,位於冷藏用冷卻器 24的下方而設有排水管40,該排水管4〇承 冷卻器24的除霜水並排出至冰箱和 自冷藏用 由該排水管40所承接的除霜水也與由排水管μ 接的除霜水同樣地,被導至冰箱外的所述機械室2 的除霜水蒸發皿28並蒸發。 Π叮〇又 11 201211480 排水管40的左右的長度尺寸以及前後的縱深尺寸被 6又疋為大於冷藏用冷卻器24的左右的長度尺寸以及前後 的縱/木尺寸’以構成為全部承接從冷藏用冷卻器24滴落的 除霜水的大小。 在所述蔬菜室4的後方,位於排水管4〇的下方而配設 有冷藏用送風機35,並且設有送風導管42及吸入口 43。 其中,送風導管42以上端部迂回排水管4〇的方式而連通 於冷藏用冷卻器室36 (冷氣導管34)。吸入口 43在蔬菜室 4内開口。 在構成冷藏室3的底部(微凍室14的底部)的分隔壁 10的後部的下表面’如圖1、圖9、圖1〇所示,位於蔬菜 室4的上部而安裝有保鮮蓋(criSper c〇ver) 72,在該保鮮 蓋72與分隔壁1〇之間’形成有遍及左右方向而延伸的通 氣路73。 如圖9所示’在分隔壁10的後部,位於微康室14的 後方而設有由多個開口部構成的通氣口 74a,並且在小物 盒16的設置部的後方也設有由多個開口部構成的通氣口 74b。 這些通氣口 74a、74b使微凍室14與通氣路73之間以 及小物盒16的設置部與通氣路73之間連通。通氣路73 的左右兩側部開放,且連通於蔬菜室4的上部。 而且,在分隔壁10的後部的右角落部,如圖5所示, 位於微珠室14的後方而形成有由多個開口部構成的連通 口 75。在這些連通口 75的下方,如圖9以及圖1〇所示, 12 201211480 設有V導管76。 该V導管76的上端部經由連通口 75而連通於微凍室 14、’下端部經由保鮮蓋72上形成的通氣口 77(參照圖10) 而連通於蔬菜室4的上部。 、此時,微凍室14中的通氣口 74a以及連通口 75作為 成為微凍室14内的空氣的出口的空氣出口而發揮功能。而 且,,些通氣口 74a以及連通口 75配置在將微凍盒18收 納於微康室14⑽狀態下,未被該财盒18所堵塞的位 置處。 ^ 物盒16的設置部中的通氣口 74b作為小物盒16的 設置部的空氣出口而發揮功能,而且,配置在收納小物盒 16的狀態下未被該小物盒16堵塞的位置處。 在此結構中,當驅動冷藏用送風機35時,主要如圖j 的空心箭頭所示,蔬菜室4内的空氣從吸入口 43被吸入至 冷藏用送風機35側,該吸人岐氣被吹出向送風導管42 側。 ^被吹出向送風導管42侧的空氣通過冷氣導管34 (冷 藏用冷卻器室36以及冷氣供給導管37)而從多個冷氣^ 給口 39吹出至冷藏室3内,並且如後所述,也被直接吹 至微滚室14内。 、吹出至冷藏室3内以及微殊室14 (也包括小物盒16 以及蛋盒15的設置部)⑽空氣主要如圖9的箭頭〇所 示,從通氣口 74a、傷流出到通氣路73,並朝向左方向 以及右方向流輯氣路73,再通過難室4的上部盒12 13 201211480 的左右兩外表面而供給至蔬菜室4内。 而且,微凍室Η内的空氣的一部分如圖1〇的箭頭C2 所示進行以下循環,即,從連通口 75通過V導管76,並 從通氣口 77供給至蔬菜室4内’供給至蔬菜室4内的空氣 最終被冷藏用送風機35吸入。 在此過程中’通過冷藏用冷卻器室36内的空氣經冷藏 用冷卻器24冷卻後成為冷氣,該冷氣被供給至冷藏室3、 械束至14以及蔬菜室4 ’由此使冷藏室3、微象室14以及 蔬菜室4被冷卻至冷藏溫度段的溫度。 另外,如後所述,通過冷藏用冷卻器24後的冷氣的— 部分被直接供給至微康室14 ’由此,微來室14被維持為 比冷藏室3以及蔬菜室4低的溫度(〇°C〜1。〇。 在冷氣導管34中的冷藏用冷卻器室36的前表面側, 如圖2、圖4所示,從前方觀察在右侧,且位於微凍室14 的後方而可裝卸地設有霧用專用導管45。 該霧用專用導管45也如圖5〜圖8所示,由冷藏用冷 卻器室36的前部壁36a及安裝在冷藏用冷卻器室36的前 表面的導管構成構件46所形成,從而成為形成霧用專用導 管45的導管構成構件46相對於前部壁36a而可裝卸的構 成。 此時’霧用專用導管45沿著前部壁36a而形成為左右 方向較長且前後方向的縱深尺寸較小的扁平的矩形箱狀。 並且,在該霧用專用導管45内,收納有靜電霧化裝置48 的主體部’該靜電霧化裝置48構成用於產生霧的霧產生裝 201211480 靜電霧化裝置招除了作為霧產生(放出)機構以外, ,作為除g成分產生機構、除臭成分產生機構而發揮功 能。=下丄對該靜電霧化裝置48進行詳述。 霧化裂置48如圖u所示,具備了具有霧放出部 〇的e產生單元(umt) 51以及用於對霧放出部5〇施加 負的高電壓的電源農置(變壓器(tmnSf_er))52而構成。 霧^生單元51具備對霧放出部50供給水分的供水部 53供水。卩53具有沿左右方向延伸的水平部53a以及從該 ίΓ°Ρ、53α的右端部向下方延伸的垂直部53b,且從正面 ”呈逆乙予狀,該霧產生單元51是在呈L·字狀的盒54 内收納保水材料55而構成。 因此’供水部53在水平部53a與垂直部53b之間具有 ’ =53:。供水部53巾的水平部❿與垂直部伽是以 二! 34中的冷藏用冷卻器室36的前部壁36a成平 仃的方式’沿著前部壁恤而配置。 日二Ϊ材料55例如呈使纖維纏繞而成的氈(felt)狀, 保水材料55 是連續發泡體。 供水部53 &办以及保水性優異’並利用毛細管現象來吸取後述 奋器56 (儲水部)内儲存的水(除霜水)。另外,201211480 VI. Description of the Invention: [Technical Field to Be Invented] Embodiments of the present invention relate to a refrigerator. [Prior Art] In recent years, in a domestic refrigerator, for example, a mist generating device (sterilization component generating mechanism) that uses electrostatic atomization to generate mist is known, and the mist generated by the mist generating device is supplied to the refrigerating chamber. Waiting for the storage room of the refrigerator. In this case, the mist generated by the mist generating device contains a sterilizing component such as a hydrolytic hydroxyl radical (hydrmoxyl radicai) or a skunk, so that the supply target of the mist can be expected to be removed. [Prior Art Document] ''' [Patent Document] [Patent Document 1] Japanese Patent Laid-Open No. Hei. No. 2006-57999 (Patent Document 2) Japanese Patent No. 4052353 A In a domestic refrigerator, there is a l borrowing; Therefore, it is possible to provide a micro-fishing compartment, and if it is to use a refrigerator generating device (sterilization component generating mechanism) that passes through a cooler, a plurality of storage chambers will be placed. The room, the staff room may have 'two to contain rhyme, therefore, provide a kind of refrigerator, which will be loaded from the fog; The mist emitted by the generating mechanism is supplied to: (in the sterilization box, the vegetable compartment can be prevented from being too cold. a, a plurality of storage compartments 6 201211480 and the refrigerator of the ancient embodiment includes: a refrigerator body, a cooler, disposed in the refrigerator body, for cooling the to the 'air blower' to make the micro; the air of the east chamber contacts the cooler and the second and the sterilization component generating mechanism generate The sterilizing component 'and the sterilizing component generating means are disposed in the micro-freezing compartment, and the sterilizing component produced by the sterilizing component generating means is supplied to the micro-freezing compartment. 'The above-mentioned and other objects, features and advantages of the present invention can be easily realized by the sterilization or deodorization of the micro-chambers for storing meat or fish, etc. The preferred embodiments are hereinafter described, and the accompanying drawings are attached. The drawings are described in detail below. [Embodiment] Box). In the following description, the same reference numerals will be given to the refrigerators in the respective embodiments, and the same reference numerals will be given to the same components in the respective embodiments, and the description will be omitted. (First embodiment) First, the first embodiment will be described with reference to Fig. 1 to Fig. 11. As shown in Fig. 1 and Q2, the ice phase main body 1 is in the heat insulating box 2 formed by a vertically long rectangular box having a front surface, and is vertically moved. Specifically, a plurality of storage compartments are arranged in series, and in particular, in the heat insulating box 2, refrigerating=3, vegetable compartment 4 is sequentially provided from the upper section, and an ice making compartment 5 and small are arranged in the left and right.冻 Freezer compartment 6, with a freezer compartment below them. 7 201211480 Water to 5, equipped with a well-known automatic ice-making device 8 (seeding blood into the baby +, the thermal insulation phase 2 is basically made of steel plate The outer casing 2a and the inner casing 2b made of I:! are provided with a heat insulating material 2c. The storage compartment I and the vegetable compartment 4 are storage compartments of the refrigerating temperature section, and the cold is as follows: The vegetable compartment 4 is partitioned by a partition wall 10 made of plastic. Usually, the maintenance temperature of the refrigerating compartment 3 is set to rC 〜 5 ° C, 1 The temperature is set to be slightly higher than 2 ° C ~ 6 C. Blocking the front surface of the 3, with a hinge (hinSe) open and close type 13⁄4 hot 3a, name: $矣$ —1 j ^ . The top surface of the _ _L to 4 is provided with a suction-type heat insulating door 4a. The lower case u constituting the storage container is connected to the rear portion of the D Γ and the person 4a. The lower upper portion is provided smaller than the lower case 11 The upper box 12 is refrigerated into 3 and divided into a plurality of sections by a plurality of shelves 13 as shown in Fig. =, the lowermost part in the refrigerating compartment 3 (the upper part of the partition wall 1〇), the right side; Chilled) 14, on the left side thereof, an egg box 15 and a small box 16 are provided above and below, and further, a tank 17 is provided on their left side. The phase storage tank 17 is for storing and supplying to the automatic ice making device 8. The water of the ice making box 8a is detachably provided by a user. In the micro-freezing chamber 14, a micro-frozen box 18 (corresponding to a container) is provided in an entrance and exit. From the upper portion of the micro-freezing chamber 14 to the storage tank A mounting plate 70 is provided on the upper portion of the portion of the portion 17. As shown in Fig. 9, a partitioning plate 71 is provided between the micro-freezing chamber 14 and the egg box 15 and the installation portion of the small-sized box 16. a, and a partitioning plate 8 201211480 71b is also provided between the egg cartridge 15 and the installation portion of the object box 16 and the installation portion of the water storage tank 17. The a mounting plate 70 constitutes the top plate portion of the micro-freezing chamber 14, and is slightly frozen. The upper portion of the chamber 14 is closed by the mounting plate 7Q. The front surface of the east chamber 14 is closed by the front surface wall 18a of the microbead box 18 in the storage state. The temperature of the micro-freezing 14 is lower than that of the upper refrigerating chamber 3 and The lower vegetables are slightly lower than 4, for example, 〇O to rc. The micro-freezing chamber 14 and the lower vegetable compartment 4 are vertically adjacent to each other via the partition wall 10. As shown in FIG. 1 and FIG. 10, in the rear upper portion of the micro-frozen box 18, specifically, the 'upper upper and lower sides of the left and right side walls of the micro-frozen box 18 are viewed from the front to the upper part of the rear beta wall'. A notch portion 18b is formed in a manner in which the front portion of the 18a and the left and right side walls is lower. The ice making compartment 5, the small freezing compartment 6 and the freezing compartment 7 are both in the freezing temperature section (for example, about 18 C), the storage compartment 'vegetable compartment 4 and the ice making compartment 5 and the small cold; the east compartment 6 is insulated by heat. The partition 19 is vertically partitioned. The front surface portion of the water chamber 5 is provided with a suction-type heat insulating door 5a, and the ice storage container 2 is connected to the back portion of k = hot 5a. In the small freezer compartment 6, although not shown in the figure, the door i is connected to the storage container. In the front surface portion of the cold room 7, there is also a suction-type heat insulating door 7ae connected to the storage facility 22, which is equipped with a cold cooler 24 and a cooler 25 $ 2 Cooling ring of the cooler ((10)), the two vegetables 24 are used for the refrigerating temperature section, that is, the refrigerating compartment 3, for the cooling, the cold phase cooler, the east/span section of the storage chamber That is, the ice making compartment 5, the small freezing compartment ό 201211480, and the freezing compartment 7 are cooled. A machine room 26 is provided on the back side of the lower end portion of the refrigerator body 1. A compressor 27 and a condenser that constitute a refrigeration cycle are disposed in the machine room 26, and a cooling fan for cooling them is disposed. (fan) or defrosting water evaporates solitary 28 and so on. A control device 29 such as a micro computer that controls the entire body is provided on the lower portion of the rear surface of the refrigerator body 1. The refrigerating cooler 24 and the cold cooler 25 are indirectly electrically connected to the outer casing 2a via a compressor 27 or the like which constitutes a cold bead cycle together with these coolers 24 and 25. On the back of the cold beam chamber 7 in the refrigerator body 1, a cold room cooler chamber 30 is provided. In the refrigerating cooler chamber 30, the cooling cooler 25, a defrosting heater (not shown), and the like are disposed at the lower portion, and are disposed at the upper portion to be provided with a cooling air supply. Fan 31. A cold air blowing port 3a is provided at an intermediate portion of the front surface of the cold beam cooler chamber 30, and a return port 30b is provided at the lower end portion. In this configuration, when the cooling blower fan 31 is driven, the cold air generated by the cold cooler 25 is supplied from the cold air outlet 3〇a to the ice making to 5, the small cold, the east chamber 6, and the cold. ; East to 7, and then return to the cold from the return port 3 ;; East with the cooler inside the chamber 3 的 cycle. By this cold air, the ice making compartment 5, the small freezing compartment 6, and the freezing compartment 7 are cooled. Further, a drain pipe 32 for receiving defrosting water during defrosting of the cooling cooler 25 is provided in a lower portion of the chiller 25 for freezing. The defrosted water received by the drain pipe 32 is led to the frost water evaporating dish 28 of the 201211480, which is provided in the machine room 26 outside the refrigerator, and is evaporated. Further, in the refrigerator compartment 3 and the back of the vegetable compartment 4 in the refrigerator main body 1, a refrigerating cooler 24 or a cold air generated by the refrigerating cooler 24 is supplied to the refrigerating compartment in the following manner. 3 (and vegetable compartment 4), a cold air duct 34, a refrigerating blower 35 for circulating the cold air, and the like. In other words, the refrigerating cooler chamber 36 constituting a part of the cold air duct 34 is provided in the rear of the lowermost stage of the refrigerating compartment 3 (the rear side of the micro-freezing chamber 14) in the refrigerator main body 1, and is in the refrigerating cooler chamber 36. A refrigerating cooler 24 is provided. A cooling air supply duct 37 that extends upward is provided above the refrigerating cooler chamber 36. The upper end portion of the cold-cooling cooler chamber 36 communicates with the lower end portion of the cold air supply duct 37. At this time, the cold air duct 34 is constituted by the refrigerating cooler chamber 36 and the cold air supply duct 37. The front wall 36a of the refrigerating cooler chamber 36 protrudes further toward the cold air supply duct 37. Further, a heat insulating material 38 having heat insulating properties is provided on the back side of the front wall 36a. In the front portion of the cool air supply duct 37, there are a plurality of cold air supply ports 39 that open into the refrigerating chamber 3. The lower portion of the refrigerating cold chamber 36 is located below the refrigerating cooler 24, and is provided with a drain pipe 40 that circulates the defrosted water of the cooler 24 and discharges it to the refrigerator and self-refrigerated. Similarly to the defrosted water connected to the drain pipe μ, the defrosted water received by the drain pipe 40 is guided to the defrosted water evaporating dish 28 of the machine room 2 outside the refrigerator and evaporated. Π叮〇又11 201211480 The left and right length dimensions of the drain pipe 40 and the front and rear depth dimensions are further increased by 6 to be larger than the left and right length dimensions of the refrigerating cooler 24 and the longitudinal/wood dimensions of the front and rear to constitute all of the refrigerated The size of the defrosting water dripped with the cooler 24. At the rear of the vegetable compartment 4, a refrigerating blower 35 is disposed below the drain pipe 4'', and a blower duct 42 and a suction port 43 are provided. The air duct 42 is connected to the refrigerating cooler chamber 36 (cooling duct 34) so that the upper end portion of the air duct 42 bypasses the drain pipe 4'. The suction port 43 is opened in the vegetable compartment 4. The lower surface ' of the rear portion of the partition wall 10 constituting the bottom of the refrigerating compartment 3 (the bottom of the micro-frozen compartment 14) is placed on the upper portion of the vegetable compartment 4 and is provided with a fresh-keeping cover as shown in Figs. 1, 9, and 1( criSper c〇ver) 72, between the fresh-keeping cover 72 and the partition wall 1', a ventilation path 73 extending in the left-right direction is formed. As shown in Fig. 9, in the rear portion of the partition wall 10, a vent 74a composed of a plurality of openings is provided behind the micro-compartment 14, and a plurality of vents 74a are provided behind the installation portion of the small-box 16 A vent 74b formed by the opening. These vents 74a and 74b communicate between the freezing chamber 14 and the air passage 73 and between the installation portion of the small box 16 and the air passage 73. The left and right side portions of the air passage 73 are open and communicate with the upper portion of the vegetable compartment 4. Further, in the right corner portion of the rear portion of the partition wall 10, as shown in Fig. 5, a communication port 75 composed of a plurality of openings is formed behind the microbead chamber 14. Below these communication ports 75, as shown in Figs. 9 and 1B, 12 201211480 is provided with a V-duct 76. The upper end portion of the V-duct 76 communicates with the micro-freezing chamber 14 via the communication port 75, and the lower end portion communicates with the upper portion of the vegetable compartment 4 via the vent hole 77 (see Fig. 10) formed on the fresh-keeping cover 72. At this time, the vent 74a and the communication port 75 in the micro-freezing chamber 14 function as an air outlet that serves as an outlet for the air in the micro-freezing chamber 14. Further, some of the vents 74a and the communication port 75 are disposed at a position where the micro-freezer 18 is received in the micro-compartment 14 (10) without being blocked by the cartridge 18. The vent 74b in the installation portion of the cartridge 16 functions as an air outlet of the installation portion of the small box 16, and is disposed at a position where the small box 16 is not blocked in a state in which the small cassette 16 is housed. In this configuration, when the refrigerating blower 35 is driven, as shown by the hollow arrow in Fig. j, the air in the vegetable compartment 4 is sucked from the suction port 43 to the side of the refrigerating blower 35, and the sucking air is blown out. Air supply duct 42 side. The air blown to the side of the air supply duct 42 is blown out of the plurality of cold air supply ports 39 into the refrigerating chamber 3 through the cold air duct 34 (the refrigerating cooler chamber 36 and the cold air supply duct 37), and as will be described later, It is directly blown into the micro-rolling chamber 14. Blowing out into the refrigerating compartment 3 and the micro-chamber 14 (including the small box 16 and the setting portion of the egg box 15) (10) The air mainly flows out from the vent 74a and the wound to the air passage 73 as indicated by an arrow 〇 in FIG. The gas path 73 is flowed in the left direction and the right direction, and is supplied to the vegetable compartment 4 through the left and right outer surfaces of the upper case 12 13 201211480 of the difficulty chamber 4. Further, a part of the air in the micro-freezing chamber is circulated as shown by an arrow C2 in FIG. 1A, that is, from the communication port 75 through the V-duct 76, and is supplied from the vent 77 to the vegetable compartment 4 to be supplied to the vegetables. The air in the chamber 4 is finally sucked in by the refrigerating blower 35. In the process, the air in the cooler chamber 36 is cooled by the refrigerating cooler 24 to become cold air, which is supplied to the refrigerating chamber 3, the bundle 14 and the vegetable compartment 4', thereby causing the refrigerating compartment 3 The micro-image chamber 14 and the vegetable compartment 4 are cooled to a temperature of the refrigerating temperature section. Further, as will be described later, the portion of the cold air after passing through the refrigerating cooler 24 is directly supplied to the micro-compartment 14', whereby the micro-chamber 14 is maintained at a lower temperature than the refrigerating chamber 3 and the vegetable compartment 4 ( 〇°C~1. 〇 The front surface side of the refrigerating cooler chamber 36 in the cold air duct 34 is located on the right side as viewed from the front and is located behind the micro-freezing chamber 14 as shown in Figs. 2 and 4 . A special duct 45 for fog is provided in a detachable manner. The special duct 45 for mist is also provided by the front wall 36a of the refrigerating cooler chamber 36 and the front of the refrigerating cooler chamber 36 as shown in Figs. 5 to 8 . The duct constituent member 46 formed on the surface is configured to be detachable from the front wall 36a by the duct constituent member 46 forming the special duct 45 for mist. At this time, the special duct 45 for mist is formed along the front wall 36a. It is a flat rectangular box shape which is long in the left-right direction and has a small depth dimension in the front-rear direction. Further, in the special duct 45 for mist, the main body portion of the electrostatic atomizing device 48 is housed. In the fog generating fog generation 201211480 electrostatic atomization device In addition to the mist generation (release) mechanism, it functions as a g component generation mechanism and a deodorization component generation mechanism. The lower portion of the electrostatic atomization device 48 is described in detail. The atomization crack 48 is as shown in Fig. An e-generation unit (umt) 51 having a mist discharge unit 以及 and a power supply farm (transformer (tmnSf_er)) 52 for applying a negative high voltage to the mist discharge unit 5 are provided. The mist generation unit 51 is provided. The water supply unit 53 that supplies water to the mist discharge unit 50 is provided with water. The crucible 53 has a horizontal portion 53a extending in the left-right direction and a vertical portion 53b extending downward from the right end portion of the Γ°°, 53α, and is inverted from the front side. In the case of the mist generating unit 51, the water retaining material 55 is housed in the L-shaped box 54. Therefore, the water supply unit 53 has '=53: between the horizontal portion 53a and the vertical portion 53b. The horizontal portion ❿ and the vertical portion gamma of the 53 towel are disposed along the front wall panel in such a manner that the front wall 36a of the refrigerating cooler chamber 36 in 34 is arranged in a horizontal manner. a felt-like felt, the water-retaining material 55 is continuous The water supply unit 53 & and the water retention is excellent, and the capillary water is used to absorb the water (defrost water) stored in the device 56 (water storage unit) described later.
° 的水平部53a配置在霧用專用導管45内的 直。卩53b的下端部如圖$所示’貫穿導管構成 勺下部、冷藏用冷卻器室36的前部的段部36b所 稍靠右,垂直部 構件46的下部、 201211480 形成的孔而插入至冷藏用冷卻器室36内的下部 保水材料55的外周是由盒54所覆蓋。在保。 中’也可使水平部53a的部分與垂直部53 的構件所構成。 』丨刀由不同 在冷藏用冷卻器t 36内的下部的前部,設有 部的儲水容器56 (參照圖8)。該儲水容器兄位 冷卻器24與存在于其下方的排水管4〇之間且供水= 的下方,杨將前部安裝於冷藏用冷卻器室%的 36a的下部36c,從而設置成向後方突出的縣 此時,安裝著儲水容器56的前部的下;;6^於前部 壁的下方且經由段部挪而向前部壁3以更前方凸出 (突出)。 =果將前部壁36a設為第!突出部,則下部36c將成 為向其更前方突出的第2突出部。财容^ %在安裝於下 部36c的安裝狀態下,自冷藏用冷卻器24鄉成冷藏用冷 卻器室36的後表面的内箱2b遠離。冷藏用冷卻_ 24與形 成冷藏用冷卻器36的後表面的内箱外接觸。 在儲水容H 56與内箱2b之間,確保有規定距離(此 時,空間距離為20 mm以上,沿面距離為3〇醒以上) 作為電性絕緣距離。而且’儲水容器%也與冷藏用冷卻器 24隔開’在儲水容a 56與冷藏用冷卻^ %的下表面之 間,確保有規定距離(此時,空間距離為2〇mm以上,沿 面距離為3〇 mm以上)作為電性絕緣距離。另外,電性絕 緣距離疋根據電氣用品安全法的規定而設計。 201211480 46 53中的垂ί部53b的下端部貫穿導管構成構件 、=、冷藏用冷部器室36的前部的段部36b所形成 的孔,並從上方插入至儲水容器56内。 =容器56承接從冷藏用冷卻器%祕的除霜水並 。供水部53的保水材料55如上所述,利用毛細 來吸取儲水容器56内儲存的水(除霜水)並供 務放出部50。 在儲水容器56的後部側的前端部的上部,形成有設定 =^他部分低的溢水部56a (參照圖8),#儲水容器兄 内儲存的水溢出時,將從溢水部56a溢出。 該溢水部56a位於所述排水管4〇的上方,從該溢水部 ^溢出的水由排水㈣所承接,並被排㈣機外的除霜 水蒸發皿28。 在供水部53中的水平部仏上,設有霧放出部. 霧放出部50是由分別構成突部的多根 構成(參顯11)。 m HPm) 57 霧放出銷57是在水平部53a的上部侧朝上地,由多根 此時為4根霧放出銷57排列成左右方向的横一列狀且分 隔開而配置,並且,在水平部53a的下部側朝向地,: 根此時為4根霧放出銷57排列成左右方向的橫一 別隔開而配置。 77 因此,霧放出部50是由朝向不同的方向(上方與 突出的多個霧放出鎖(突部)57構成。霧放出部& 置成,多個霧放㈣(突部)57將供水部Μ的水平部^ 17 201211480 夾在中間而向上下相反的方向延伸。 而且,多個霧放出銷(突部)57配置成上下兩段。各 霧=出銷57是以與冷氣導管%中的冷藏用冷卻器室% 的刖部壁36a成平行的方式沿著該前部壁3如而配置。霧 放出部50設在冷藏室3的下方後部且鄰接於蔬菜室4的位 置,且配置在微凍室14的襄部。 各霧放出銷57例如是將聚g旨(pC)iyester)纖維和作為 導電性物質的碳(e arb G n )纖維混合齡而形成為銷狀(棒 狀)者,具有保水性及水的吸取特性,並且具有導電性。 各霧放域57承載著麵奈米膠體(nan。choroid)。麵 奈米膠體例如可通過將霧放㈣57浸潰到含核奈米膠 體的處理液巾,並對魏行錢而承載。 " 各霧放出銷57的底端部貫穿供水部Μ的盒%而接觸 保水=料55。在供水部53巾的水平部53&的左端部,以 朝左犬出的方式有構成受電用電極的受電銷%。受電 銷58的底端部在盒54内接觸保水材料^。 電源裝置52在霧用專用導管45内,位於霧產生單元 51的左側而呈m&狀&地設置著。在該電源裝置52的右 端部’設有連結著導線6〇且由緊固(fasten)(平型)端子 構成的供電端子61,在呤& 、丁主 - α 在該供電端子61上連接著霧產生單 7L 51的所述受電銷58。 *雷Π: 如眾所周知般,具備包含將高頻電源(交 =直流的高壓變壓器的整流電路或升壓電路 專,產生負的向電壓(例如術),並經由供電端子61而 201211480 輸出至受電銷58。 由保:料t自的電的負的高電壓從受電銷58經 放_帶負電;:施:ΐ各霧放出銷57 ’使得各霧 i Αr 土 ® 、 且,此時,冰箱本體1的外箱2a經 由地線(未圖示)等而接地。 以方式構成的靜電霧化打48中,在儲水容器 πτ ^二呆水材料55吸取並供給至各霧放出銷57的狀態 ’、放出—銷57施加來自電源裝置52的負的高電壓。 ,時’電何集中於各霧放出銷57的前端部,對該前端 ^所含的錢予超過表祕力醜量(_gy)。由此,各 霧放出銷57的前端部的水發生分裂(雷氏分裂,Rayleigh fission),並由前端部呈微細的霧狀而放出(靜電霧化 象)〇 旦此處,呈霧狀放出的水粒子帶負電,並包含通過該能 I而生成的除菌成分、除臭成分即羥自由基(hydroxyl radical)。 因而,具有強氧化作用的羥自由基從各霧放出銷57 與霧一同被放出,通過羥自由基的作用可進行除菌或除 臭。此時’未設置與帶負電的霧放出銷57對應的相對電極。 因此,來自霧放出銷57的放電自身變得非常平緩,不 會在放電電極與相對電極之間產生電暈(c〇r〇na;)放電, 從而可抑制有害氣體(臭氧(ozone)、或臭氧使空氣中的 氮發生氧化而產生的氮氧化物、亞硝酸、石肖酸等)的產生。 此處,霧放出銷57 (霧放出部50)可稱作是放出經自 19 201211480 由基曰這除菌成分(也是除臭成分)的除菌成分放出機構 (也是除臭成分放$機構),靜冑霧化裝置48可稱作是除菌 成分產生機構(除臭成分產生機構)。 >在構成霧用專用導管45的後壁的冷藏用冷卻器室36 ,刖部壁36a,設有霧用冷氣供給口 62(參照圖4、圖7)。 该霧用冷氣供給口 62是在不與霧放出部5G中的霧玫出銷 57相向的位置,此時是在霧放出部50更左側,配置於電 源裝置52的上方。 ,霧用冷氣供給口 62的後部貫穿隔熱材料38且連通 至冷氣導管34中的冷藏用冷卻器室36,且前部連通至露 用專用導管45。 因此,通過冷氣導管34内的冷氣的一部分從該霧用冷 氣供給口 62供給至霧用專用導管45内(參照圖7的箭頭 A1)。從霧用冷氣供給口 62供給至霧用專用導管翎内的 冷氣在霧用專用導管45内形成對流。 在霧用冷氣供給口 62的上方,位於冷藏用冷卻器室 36的前部壁36a的背侧而設有向上方延伸的面向冷藏室的 霧用導管63 (參照圖4、圖7)。該面向冷藏室的霧用導管 63的下端部在霧用專用導管45内開口而成為冷藏室用^ 吹出口 63a,上端部連通至冷氣導管34中的冷氣供给導管 37 内。 、口 因此,在霧用專用導管45内產生的霧的一部分從冷藏 室用霧吹出口 63a通過面向冷藏室的霧用導管63、冷^供 給導管37 ’並從冷氣供給口 39供給至冷藏室3内(參照 201211480 圖4、圖7的前頭B1)。 在霧用專用導管45中的導管構成構件46的前表面部 (與上表面不同的位置),位於霧用冷氣供給口 62的上方而 設有微凍室用霧吹出口 65 (參照圖4、圖7),從該微凍室 用霧吹出口 65將霧的一部分供給至微凍室14内(參照圖 4、圖7的箭頭B2)。 微凍室用霧吹出口 65呈向導管構成構件46的前表面 部更前方突出的朝前的筒狀,並且位於微凍盒18的後部壁 的上端(切口部18b)更上方(參照圖9),包含從微凍室 用霧吹出口 65吹出到微凍室14内的霧的空氣大多從微凍 盒18的後上部的切口部18b供給至微凍盒18内。 而且,在導管構成構件46的前表面部,位於微凍室用 霧吹出口 65的左侧而設有蛋盒用霧吹出口 66(參照圖4), 霧的一部分從該蛋盒用霧吹出口 66也被供給至蛋盒15内 (參照圖4的箭頭B3)。 進而,在霧用專用導管45的右側的下部,如圖5所示, 設有蔬菜室用霧吹出口 67。該蔬菜室用霧吹出口 67連通 于連通口 75,霧用專用導管45内的霧的一部分通過蔬菜 室用霧吹出口 67、連通口 75、V導管76、通氣口 77也被 供給至蔬菜室4内(參照圖10的箭頭C2)。 此時,蔬菜室用霧吹出口 67的合計開口面積S1被設 定為小於微凍室用霧吹出口 65的合計開口面積S2 (Sl< S2)。 而且,在圖4中,向霧用專用導管45内吹入冷氣的霧 21 201211480 用冷氣供給口 62與蔬菜室用霧吹出口 67之間的 被設定為大於霧用冷氣供給口 62與微;東室 離= 之間的距離L2(L1>L2)。 務人出口 65 進而,如圖11所示,在霧用專用導管45的 構件46上,位於成為蔬菜室用霧吹出口 67的上游= 方而設有通路縮窄壁67a。該通路縮窄壁67 ^ 霧用專科管45⑽空驗向蔬菜㈣敎= 路67b進行縮窄的形態。 67的通 在霧用專料管45壯部,位 而設^财室用冷氣供給口⑽(參照圖4、圖6圖的8上)方 用冷氣供給口 68如圖6、圖8以及圖9所亍,呈 向導管構成構件46的前表面部更前 斤:呈 狀,並且位於微康盒18的後 丄的筒 微凉室用冷氣供终口 Μ :上%更上方(參照圖9 )。 通至冷藏用冷卻器室、36,十二部貫穿隔熱材料38而連 通至微凍室14。 則〇貝穿霧用專用導管45而連 因此,冷藏用冷卻考宕] 室用冷氣供給口 68 ,、氣的一部分通過該微凍 8的箭頭A2),以將微;束室^^至微凌室14(參照圖6、圖 室4低的溫度即〇«c〜rc '·’持為比冷藏室3以及蔬菜 藏用冷卻器24與霧放出°而且’隔熱材料%也兼作冷 其次,對上述a之間的絕緣機構。 冷藏室3以及蔬菜^ 4的作用進行敍述。如上所述,在對 冷卻後的冷氣借助進订冷卻時’經冷藏用冷卻器24 送風機35的送風作用,主要如圖 22 201211480 1中的空心箭頭所示般,通過冷氣供給導管37,並從多個 冷氣供給口 39供給至冷藏室3内’並且,—部分冷氣二微 凍室用冷氣供給口 68直接供給至微凍室14内(參照圖6、 圖8的箭頭A2)。 ' 被供給至冷藏室3内以及微束室14的冷氡在有助於食 品等的儲藏物的冷卻之後’如上所述,主要如圖9的气頭 C1所示’從通氣口 74a、74b流出到通氣路乃,並朝=左 方向以及右方向流經通氣路73,再通過蔬菜室4 a人 12的左右兩外表面而供給至蔬菜室4内,而且,微= 内的冷氣的-部分如圖K)的箭頭C2所示,從連通口乃 通過V導管76,並從通氣口 77供給至蔬菜室4内 供給至蔬菜室4内的冷氣在有助於蔬菜等藏 =之後,從吸人口 43被狀至冷藏崎風機 = 次由冷藏用冷卻器24進行冷卻,從而重複這 a再 =’在該冷,3以及蔬菜室4的冷卻時,冷^ :部為室36_冷氣的—部分如圖7中 : 從霧用冷祕細62供給线科 f Al所不’ ,導管45内的冷氣碰到導管構成構件46= 面’從而在霧用專用導管45_成對流而擴散。6的内表 此時,當驅動靜電霧化裝置48時,從 中的多個霧放出銷57放出如上所 產生早Ml 細的霧。 有备自由基的微 不 從霧放出銷57放出的霧的一部分 如圖7的箭頭所 ’乘著對流的冷氣從冷藏室用霧吹出D63a = = 23 201211480 藏室的霧用導管63、冷氣供給導瞢λ 39供給至冷藏室3内。 ,並從冷氣供給口 而且’從霧放出銷57玫出的霧的— 7的箭頭Β2所示,從微象室用刀圖4以及圖 “内的尤其是财盒18内,並且二室 示,也從蛋盒用霧吹出口 66供給至蛋盒Η =箭頭Β3所 進而,從霧放出銷57玫出的_二二 菜室用霧吹出口 67通過連通D 75、^右下部的蔬 也供給至蔬菜室4内。 6、通氣口 77 因此,在本實施方式中,可將霧用 的霧供給至冷藏室3、微凍室14、杏各 S 5内產生 等多個供給目標’從而可期待這些供:目標4 的效果’並且也可期待蔬菜等的保濕或保鮮I菌或除臭 根據上述第1實施方式,可獲 由於採用了下述結構,即,用效果。 (霧放出機構)的靜娜_ 48設置於微^產 ^將由該靜電霧化裝置48產生的包含除g成 自 f )的霧供給至财室14,,_室14可彻從= 給Π68供給的冷氣崎卻至比 “ 菜至4低的溫度為止,能_微衫14的 = 〇c ’可容易地實現儲藏喊魚等的微杉14 臭,並且也可進行保濕或保鮮。 -菌或除 器風機%而循環的通過冷藏用冷卻 後勺工乱(冷氣)的一部分從霧用冷氣供給口 & 24 201211480 供給至靜電霧化裝置48的霧放出部5〇 (圖7)。 此時,從霧放出部50放出的霧與供給至霧 的空氣(冷氣)-同從微;東室用霧吹出σ 65吹出 Η内二並且從蔬菜室用霧吹出口 67通過連通口料而吹出 至蔬菜室4内。 此處,蔬菜室用霧吹出口 67的開口面積S1 小於微凍室用霧吹出口 65的開口面積S2,因此從=菜室 用霧吹出口 67向蔬菜室4侧吹出的風量(冷氣的量j少於 從微凍室用霧吹出口 65吹出至微凍室14内的風量 的量)。 7 ' 因此,能夠抑制從蔬菜室用霧吹出口 67向蔬菜室4 侧吹出的風量(冷氣的量),從而能夠防止:蔬菜室4因通 過冷藏用冷卻器24後的冷氣而變得過冷。 立由於將通過冷藏用冷卻器24後的空氣供給至霧放出 部5〇的霧用冷氣供給口62與蔬菜室用霧吹出口 67之間的 距離L1構成為長於所述霧用冷氣供給口 ,之間的距離u,因此從霧用冷氣供== 霧用專用導皆45内的冷氣雖易流向微;東室用霧吹出口 :但與其相比更難流向蔬菜室用霧吹出口 67側,進而, :氣難流向蔬菜室4側。借此,也能_止蔬菜室4因冷 氧而變得過冷。 在霧用冷氣供給π 62與蔬菜室用霧吹出口 65之間配 ^放出部5〇。借此’從霧放出部5〇放出的霧易流向 机采室用霧吹出σ 65,從而也能夠將霧良好地供給至蔬菜 25 201211480 室4。 由於採用了將由靜電霧化裝置48所產生的包含除菌 成分的霧也供給至與微凍室14鄰接的蔬菜室4的结構,因 此也能夠實現蔬菜室4的除g或除臭,並且也能夠實現蔬 菜等的保濕或保鮮。 由於採用了下述結構 I Η从不益W的傻上部形片 有切口部18b,從微凍室用霧吹出口 65吹出的包含除菌居 分的霧肋π㈣b供給至财盒18内,因此能夠將從德 束室用霧吹出口 65吹出的包含除菌成分的霧 供給至微凍盒18内。 而且,由於微床室用霧吹出口 65呈筒狀,因此能夠將 包含除菌成分的霧從微衫贿吹出σ 65良好地供 微凍盒18内。 由於採用了下述結構,即,微;東室 板部的載置板70所堵塞’前表面由微 18a所堵塞,因此在將微凍盒18收知认视土 』衣面壁 態下,供給至賺㈣ 外部’從而使=菌成分的霧的作 東= 内更有效地發揮作用。 做果至14 在微凍室14中,設有成為微凍室14 通氣口 74a及連通口 75,微凍室 介二氣9出口的 口 74a及連通口 75流出到微凍室14 2的广氣分別從通氣 易地接受從微來室用霧吹出口 65 _、#夕—部/因此能夠容 菌成分的霧雜給。 ⑼衫心的包含除 26 201211480 採用了下述結構,即,在微凍室丨4的底部設有使微束 室14與蔬菜室4連通的連通口 75,且微凍盒18未堵塞連 通口 75。由此,即使在微凍室14内收納有微凍盒18的狀 態下,也能夠確保連通口 75,從而能夠確保包含通過該連 通口 75的霧的空氣的流動。 由於採用了下述結構’即’靜電霧化裝置48具有承接 並儲存冷藏用冷卻器24的除霜水的儲水容器56,對該儲 水容器56内的水進行霧化’並將包含除菌成分的霧供給至 微凍室14,因此如上所述,可將包含除菌成分(羥自由基) 的霧供給至微凍室14,從而可實現微凍室14的除菌或1除 臭’並且也可實現保濕或保鮮。 “ 而且’靜電霧化裝置48中所用的水是利用了儲水容器 56内儲存的冷藏用冷卻器24的除霜水,因此能夠自動地 進行對儲水容器5 6的供水,從而能夠省去使用者(用 進行供水的工夫。 由於冷藏用冷卻器24設置在微凍室14的後方,因此 可利用微;東室14附近的冷朗冷卻器24的除霜水來 靜電霧化裝置48中使用的水。 本實施方式的冷;東冰箱採用了具備冷藏用冷卻器Μ 方這2個冷卻器的雙蒸發器一― 本魏方式般的採㈣紐11方式的冷冰循 3=的冷来用冷卻器25的周邊溫度或單』 .的冷卻11的周邊溫度在_時相除霜加 27 201211480 熱器的加熱而成為正的溫度 -20°C以下的溫度。 但在除霜時以外會始終保持 問題因此,存在難以穩定地對觀料%進行水的供給的 ,於此點’在本實施方式中’在 % 器25這2個冷卻器的雙蒸發器水4 的結構。 56叹置在冷藏用冷卻n 24下方 邊:田^式的冷凌冰箱中,冷藏用冷卻器24的周 冷藏科卻1 24的冷卻運射會成為負 (mmus )溫度,但仍遠高於冷_冷卻器25的溫度,並= 卩125 _卻運轉中(冷;東溫度段的儲藏室的 1/壓縮機27的運轉停止巾,會借助冷藏用送風機 =的工氣循環而上升至接近冷藏室3的溫度的机附近為 因此,設置在冷藏用冷卻器24下方的儲水容器%内 的水難以結冰,而且,即使結冰也易融化n 定地對霧放出部5G進行水的供給。 _ 靜電霧化裝置48的霧放出部50是由朝向不同的方向 突出的多個霧放出銷(突部)57所構成。借助該結構,與 霧產生用的突部的突出方向僅為單向的情況不同,可將霧 28 201211480 Ί二设為多個方向,從而可加寬霧的供給範圍。The horizontal portion 53a of ° is disposed in the straight conduit 45 for the mist. The lower end portion of the crucible 53b is inserted into the refrigerating portion as shown in Fig. $, the lower portion of the scooping portion, the front portion 36b of the refrigerating cooler chamber 36, and the lower portion of the vertical portion member 46 and the hole formed in 201211480. The outer circumference of the lower water retaining material 55 in the cooler chamber 36 is covered by the casing 54. In insurance. The middle portion can also be constituted by a portion of the horizontal portion 53a and a member of the vertical portion 53. The boring tool is provided with a water storage container 56 (see Fig. 8) which is different from the lower portion of the lower portion of the refrigerating cooler t36. The water storage container sibling cooler 24 and the drain pipe 4〇 existing therebelow and below the water supply=, Yang installs the front portion to the lower portion 36c of the refrigerating cooler chamber% 36a, thereby being disposed rearward. At this time, the prominent county is installed with the lower portion of the front portion of the water storage container 56; 6^ below the front wall and moved forward through the segment portion to protrude forward (project) from the front wall 3. = The front wall 36a is set to the first! In the protruding portion, the lower portion 36c will become a second protruding portion that protrudes further forward. In the mounted state in which the lower portion 36c is mounted, the inner casing 2b of the rear surface of the refrigerating cooler chamber 36 is kept away from the refrigerating cooler 24. The cooling cooling _ 24 is in contact with the outer casing forming the rear surface of the refrigerating cooler 36. Between the water storage capacity H 56 and the inner box 2b, it is ensured that there is a predetermined distance (in this case, the space distance is 20 mm or more, and the creeping distance is 3 awake or more) as the electrical insulation distance. Further, 'the water storage container % is also separated from the refrigerating cooler 24' between the water storage capacity a 56 and the lower surface of the refrigerating cooling device to ensure a predetermined distance (at this time, the space distance is 2 mm or more, the creeping distance) It is 3 〇mm or more) as an electrical insulation distance. In addition, the electrical insulation distance is designed in accordance with the provisions of the Electrical Appliances Safety Law. The lower end portion of the sag portion 53b of the 201211480 46 53 penetrates the hole formed by the duct constituting member, the front portion 36b of the refrigerating cold portion chamber 36, and is inserted into the water storage container 56 from above. = Container 56 takes over the defrosting water from the refrigerated cooler. As described above, the water retaining material 55 of the water supply unit 53 sucks the water (defrost water) stored in the water storage container 56 by the capillary and supplies it to the discharge unit 50. In the upper portion of the front end portion on the rear side of the water storage container 56, an overflow portion 56a (see FIG. 8) having a lower setting portion is formed (see FIG. 8). When the water stored in the water storage container brother overflows, the overflow portion 56a overflows. . The overflow portion 56a is located above the drain pipe 4, and the water overflowing from the overflow portion is received by the drain (4), and is discharged to the defrosted water evaporating dish 28 outside the machine. A mist releasing portion is provided in the horizontal portion 中 of the water supply portion 53. The mist releasing portion 50 is constituted by a plurality of structures each forming a projection (Ref. 11). (m HPm) 57 The mist release pin 57 is disposed on the upper side of the horizontal portion 53a, and is arranged such that a plurality of the four mist release pins 57 are arranged in a horizontal row in the horizontal direction and are spaced apart from each other. The lower side of the horizontal portion 53a faces the ground, and the roots are arranged such that the four mist release pins 57 are arranged in a horizontal direction in the left-right direction. 77. Therefore, the mist releasing portion 50 is constituted by a plurality of mist releasing locks (protrusions) 57 that are oriented in different directions (upward and protruding). The mist releasing portion & is disposed such that a plurality of mist discharges (four) (protrusions) 57 supply water The horizontal portion of the Μ ^ 17 201211480 is sandwiched in the middle and extends in the opposite direction. Further, a plurality of mist discharge pins (protrusions) 57 are arranged in two upper and lower sections. Each mist = output 57 is in the air duct with % The crotch portion 36a of the refrigerating cooler chamber is disposed in parallel along the front wall 3. The mist releasing portion 50 is provided at a lower rear portion of the refrigerating chamber 3 and adjacent to the vegetable chamber 4, and is disposed. In the crotch portion of the micro-freezing chamber 14. Each of the mist releasing pins 57 is formed into a pin shape by mixing the fibers of the poly (pC) iyester fibers and the carbon (e arb G n ) fibers as a conductive material. It has water retention and water absorption characteristics and is electrically conductive. Each of the fogging fields 57 carries a nano-colloid (nan. choroid). The surface nano-colloid can be carried, for example, by dipping the mist (4) 57 into a treatment liquid towel containing the core nanogel and carrying it on the money. " The bottom end portion of each of the mist discharge pins 57 penetrates the box % of the water supply unit 而 and contacts the water retaining material 55. In the left end portion of the horizontal portion 53 & of the water supply portion 53, the power receiving pin % constituting the power receiving electrode is provided so as to be leftward. The bottom end portion of the receiving pin 58 contacts the water retaining material ^ in the case 54. The power supply unit 52 is disposed in the m&amp;&> on the left side of the mist generating unit 51 in the special duct 45 for fog. At the right end portion of the power supply unit 52, a power supply terminal 61 to which a wire 6 is connected and which is constituted by a fasten (flat) terminal is connected to the power supply terminal 61 at 呤& The fog produces the power receiving pin 58 of the single 7L 51. *Thunder: As is well known, it has a rectifier circuit or a booster circuit that contains a high-frequency power supply (a high-voltage transformer of AC/DC, generates a negative voltage (for example, surgery), and outputs to the power receiving via the power supply terminal 61 and 201211480. Pin 58. The negative high voltage of the electric power from the power supply 58 is negatively charged from the power receiving pin 58; the application: ΐ each mist discharge pin 57 ' makes each fog i Αr soil®, and, at this time, the refrigerator The outer casing 2a of the main body 1 is grounded via a ground wire (not shown) or the like. The electrostatic atomizing device 48 configured as described above is sucked and supplied to the respective mist discharge pins 57 in the water storage container πτ^two water-repellent material 55. The state 'release' pin 57 applies a negative high voltage from the power supply unit 52. When the current is concentrated on the front end portion of each of the mist discharge pins 57, the money contained in the front end ^ exceeds the ugly amount of the secret force ( _gy), the water at the tip end portion of each of the mist release pins 57 is split (Rayleigh fission), and is discharged from the tip end portion in a fine mist shape (electrostatic atomization image). The misty water particles are negatively charged and contain the energy generated by the energy I The bacterial component and the deodorizing component are hydroxyl radicals. Therefore, the hydroxyl radical having a strong oxidizing action is released together with the mist from the respective mist releasing pins 57, and can be sterilized or deodorized by the action of hydroxyl radicals. At this time, the opposite electrode corresponding to the negatively-charged mist discharge pin 57 is not provided. Therefore, the discharge itself from the mist discharge pin 57 becomes very gentle, and no corona is generated between the discharge electrode and the opposite electrode (c〇 R〇na;) discharge, thereby suppressing the generation of harmful gases (ozone, or nitrogen oxides generated by oxidation of nitrogen in the air, nitrous acid, tartaric acid, etc.). The pin 57 (the mist releasing portion 50) can be referred to as a sterilizing component discharging mechanism (also a deodorizing component releasing mechanism) which is released from 19 201211480 by the sterilizing component (also a deodorizing component), and is quietly atomized. The device 48 can be referred to as a sterilization component generating mechanism (deodorizing component generating mechanism). In the refrigeration cooler chamber 36 constituting the rear wall of the special mist duct 45, the crotch wall 36a is provided with a cold air supply. Port 62 (refer to Figure 4, Figure 7) The mist cooling air supply port 62 is located at a position that does not face the mist flared pin 57 in the mist discharge portion 5G. At this time, the mist discharge portion 50 is disposed on the left side of the mist discharge portion 50, and is disposed above the power supply device 52. The rear portion of the port 62 penetrates the heat insulating material 38 and communicates with the refrigerating cooler chamber 36 in the cold air duct 34, and the front portion communicates with the dedicated duct 45 for the dew. Therefore, a part of the cold air passing through the cold air duct 34 is used from the mist. The cold air supply port 62 is supplied into the special duct 45 for mist (see an arrow A1 in Fig. 7). The cold air supplied from the mist cold air supply port 62 to the special duct for the mist is convected in the special duct 45 for mist. Above the mist cooling air supply port 62, a mist duct 63 (see Figs. 4 and 7) that faces upward is provided on the back side of the front wall 36a of the refrigerating cooler chamber 36. The lower end portion of the mist duct 63 facing the refrigerating chamber is opened in the special duct 45 for mist to be the refrigerating chamber outlet 63a, and the upper end portion is communicated with the cold air supply duct 37 in the cold air duct 34. Therefore, a part of the mist generated in the special duct 45 for the mist is supplied from the refrigerating compartment mist outlet 63a through the mist duct 63 facing the refrigerating compartment, the cold supply duct 37', and from the cold air supply port 39 to the refrigerating compartment 3. (refer to 201211480 Figure 4, the front B1 of Figure 7). The front surface portion (the position different from the upper surface) of the duct constituent member 46 in the special duct 45 for the mist is provided above the mist cold air supply port 62, and the mist outlet 65 for the freezing chamber is provided (see FIG. 4 and FIG. 7) A part of the mist is supplied into the micro-freezing chamber 14 from the micro-freezing chamber by the mist blowing port 65 (see an arrow B2 in Figs. 4 and 7). The micro-freezing chamber mist outlet 65 has a forward cylindrical shape that protrudes forward from the front surface portion of the duct constituent member 46, and is located above the upper end (notched portion 18b) of the rear wall of the micro-frozen box 18 (refer to FIG. 9). The air containing the mist blown into the micro-freezing chamber 14 from the micro-freezing chamber by the mist blowing port 65 is supplied from the notch portion 18b of the rear upper portion of the micro-freezing box 18 to the micro-freezing box 18. Further, in the front surface portion of the duct constituent member 46, a mist blowing outlet 66 (see FIG. 4) for the egg box is provided on the left side of the mist blowing outlet 65 of the micro-freezing chamber, and a part of the mist is also blown from the egg box mist outlet 66. It is supplied into the egg cassette 15 (refer to arrow B3 of Fig. 4). Further, in the lower portion on the right side of the special duct 45 for mist, as shown in Fig. 5, a mist outlet 67 for the vegetable compartment is provided. The vegetable compartment is connected to the communication port 75 by the mist blowing port 67, and a part of the mist in the special duct 45 for the mist is supplied to the vegetable compartment 4 through the vegetable compartment mist outlet 67, the communication port 75, the V duct 76, and the vent 77. (Refer to arrow C2 of Fig. 10). At this time, the total opening area S1 of the vegetable chamber mist blowing outlets 67 is set to be smaller than the total opening area S2 of the micro-frozen chamber mist blowing outlets 65 (S1 < S2). In addition, in FIG. 4, the mist 21 in which the cold air is blown into the special duct 45 for the mist is set to be larger than the cold air supply port 62 and the micro air supply port 67 between the cold air supply port 62 and the vegetable compartment mist outlet 67. The distance between the chambers = L2 (L1 > L2). Further, as shown in Fig. 11, the member 46 of the special duct 45 for mist is provided with a passage narrowing wall 67a located upstream of the mist outlet 67 for the vegetable compartment. The passage narrows the wall 67 ^ and the mist is narrowed by the specialist tube 45 (10) to the vegetable (4) 敎 = road 67b. The air supply port 68 is provided in the air supply port (10) (see Fig. 4, Fig. 6 and Fig. 8), and the cold air supply port 68 is shown in Fig. 6, Fig. 8 and Fig. 9 亍 呈 呈 呈 呈 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管 导管). It passes to the refrigerating cooler chamber 36, and twelve passes through the heat insulating material 38 to connect to the micro-freezing chamber 14. Then, the mussel wears the mist through the special duct 45. Therefore, the refrigerating cooling chamber uses the cold air supply port 68, and a part of the gas passes through the arrow A2) of the micro-freeze 8 to make the micro; In the venting chamber 14 (see Fig. 6, the temperature at which the chamber 4 is low, that is, the 〇«c~rc '·' is held in comparison with the refrigerator compartment 3 and the vegetable storage cooler 24, and the temperature % of the heat insulating material is also used as the cold. The function of the cooling mechanism 3 and the vegetables 4 will be described. As described above, when the cooled cold air is cooled by the order, the air blowing effect of the blower 35 through the refrigerating cooler 24 is described. Mainly as shown by the hollow arrow in 201211480 1 , it is supplied to the refrigerating chamber 3 through the cold air supply duct 37 and from the plurality of cold air supply ports 39', and the partial cold air micro-freezing chamber is directly supplied by the cold air supply port 68. It is supplied to the inside of the micro-freezing chamber 14 (refer to the arrow A2 of FIG. 6 and FIG. 8). 'The cold water supplied to the inside of the refrigerator compartment 3 and the microbeam chamber 14 after cooling the storage of foods, etc. As described above, mainly as shown by the air head C1 of FIG. 9 'flowing out from the vents 74a, 74b to the passage The air passage is, and flows through the air passage 73 in the left and right directions, and is supplied to the vegetable compartment 4 through the left and right outer surfaces of the vegetable compartment 4a, and the portion of the cold air inside the micro= As shown by the arrow C2 in Fig. K), the cold air supplied from the communication port through the V-duct 76 and supplied from the vent hole 77 to the vegetable compartment 4 and supplied to the vegetable compartment 4 contributes to the storage of vegetables, etc. 43 is shaped to the chilling fan = the second cooling by the refrigerating cooler 24, so that this is repeated = 'in the cold, 3 and the cooling of the vegetable compartment 4, the cold part: the part is the chamber 36_ cold air part As shown in Fig. 7, the cold air in the duct 45 is supplied to the duct member member 46 = face ' from the mist cold secret 62, and the air duct 45 45 is convectively diffused. The inner table of 6 At this time, when the electrostatic atomizing device 48 is driven, a plurality of mist releasing pins 57 are discharged from the mists which are generated as described above. A part of the mist that is released from the mist release pin 57 is a part of the mist that is released from the mist release pin 57. The convection air is blown out from the refrigerator by the arrow D63a == 23 201211480 The mist duct 63 of the storage room, the cold air supply The guide λ 39 is supplied into the refrigerating compartment 3. And from the air-conditioning supply port and the arrow Β2 of the fog from the fog release pin 57, the blade from the micro-image room is shown in Figure 4 and the inside of the box is especially inside the box 18, and the two compartments are shown. The egg box is also supplied to the egg carton by the mist blowing port 66. The arrow Β3 is further provided, and the _22 vegetable room which is swelled from the mist releasing pin 57 is supplied to the vegetable in the lower right portion through the mist blowing outlet 67. In the vegetable compartment 4, 6. Ventilation port 77 Therefore, in the present embodiment, the mist for mist can be supplied to the refrigerating chamber 3, the micro-freezing chamber 14, and the plurality of supply targets in the apricot S 5, and thus can be expected. In addition to the effect of the target 4, it is also expected that the moisturizing or fresh-keeping of the vegetables or the like, or the deodorization, can be obtained by the following configuration, that is, the effect is obtained. (Fog release mechanism) Jingna_48 is disposed in the micro-products to supply the mist generated by the electrostatic atomizing device 48, including g from f), to the chamber 14, and the chamber 14 can be completely supplied from the cold air supply to the crucible 68. It is easy to realize the storage of shouting fish, etc., as long as the temperature is lower than the temperature of the dish. 14 smelly, and can also be moisture or preservation. - a part of the cooling and scooping (cooling) which is circulated by the bacteria or the fan 5 is supplied from the mist cooling air supply port & 24 201211480 to the mist discharging portion 5 of the electrostatic atomizing device 48 (Fig. 7) . At this time, the mist discharged from the mist discharge unit 50 and the air (cold air) supplied to the mist are the same; the east chamber is blown out by the mist σ 65 and blown out from the vegetable chamber by the mist outlet 67 through the communication port. To the vegetable room 4. Here, the opening area S1 of the vegetable chamber mist blowing outlet 67 is smaller than the opening area S2 of the micro-frozen chamber mist blowing port 65, so that the amount of air blown from the vegetable chamber mist outlet 67 to the vegetable compartment 4 side (the amount of cold air j is less than The amount of air blown into the micro-freezing chamber 14 by the mist blowing port 65 from the micro-freezing chamber). Therefore, it is possible to prevent the vegetable compartment 4 from being excessively cooled by the cold air after passing through the refrigerating cooler 24, by suppressing the amount of air (the amount of cold air) blown from the vegetable compartment by the mist outlet 67 to the vegetable compartment 4 side. The distance L1 between the mist cold air supply port 62 and the vegetable chamber mist outlet 67 that supplies the air that has passed through the refrigerating cooler 24 to the mist discharge unit 5 is longer than the mist cold air supply port. Since the distance u is between the cold air supply for the fog, the cold air in the special guide 45 is easy to flow to the micro; the east room is blown with the mist: but it is more difficult to flow to the vegetable room with the mist blowing outlet 67 side, and further, : Gas is difficult to flow to the vegetable room 4 side. Thereby, it is also possible to stop the vegetable compartment 4 from being too cold due to cold oxygen. The discharge portion 5 is disposed between the mist supply π 62 for the mist and the mist outlet 65 for the vegetable compartment. By this, the mist discharged from the mist discharge portion 5 is easily flowed to the machine room by the mist σ 65, and the mist can be favorably supplied to the vegetable 25 201211480 chamber 4. Since the mist containing the sterilization component generated by the electrostatic atomization device 48 is also supplied to the vegetable compartment 4 adjacent to the micro-freezing chamber 14, the vegetable compartment 4 can be removed or deodorized, and It can achieve moisturizing or preservation of vegetables and the like. By using the slit portion 18b of the silly upper sheet which does not have the following structure I, the mist rib π(4)b containing the sterilizing fraction blown out from the micro-freezing chamber by the mist blowing port 65 is supplied to the box 18, so that it can be The mist containing the sterilization component blown out from the dew chamber by the mist blowing port 65 is supplied into the micro-frozen box 18. Further, since the mist blowing outlet 65 of the micro-bed chamber has a cylindrical shape, the mist containing the sterilization component can be satisfactorily supplied from the micro-shirts σ 65 to the micro-freezing box 18. Since the following structure is adopted, that is, the front surface of the mounting plate 70 of the east chamber plate portion is clogged, the front surface is blocked by the micro 18a, so that the micro-frozen box 18 is received in the wall state of the clothing surface. To earn (4) the external 'so that the fog of the ingredients of the fungus is more effective. The result 14 to the micro-freezing chamber 14 is provided with a vent hole 74a and a communication port 75 serving as the micro-freezing chamber 14, a port 74a for the micro-frozen chamber, and a communication port 75 flowing out to the micro-freezing chamber 14 2 The gas is easily received from the ventilation chamber, and the mist is blown from the micro-compartment 65 _, #夕-部/ (9) Inclusion of the core of the shirt In addition to 26 201211480, a structure is adopted in which a communication port 75 for communicating the microbeam chamber 14 with the vegetable compartment 4 is provided at the bottom of the micro-freezing chamber 4, and the micro-freezing box 18 is not blocked. 75. Thereby, even in the state in which the micro-frozen box 18 is accommodated in the micro-freezing chamber 14, the communication port 75 can be secured, and the flow of the air including the mist passing through the communication port 75 can be secured. The electrostatic atomizing device 48 having the following structure, that is, the electrostatic atomizing device 48, has a water storage container 56 that receives and stores the defrosted water of the refrigerating cooler 24, and atomizes the water in the water storage container 56 and will contain The mist of the bacterial component is supplied to the micro-freezing chamber 14, so that the mist containing the sterilization component (hydroxyl radical) can be supplied to the micro-freezing chamber 14 as described above, so that sterilization or deodorization of the micro-freezing chamber 14 can be achieved. 'And you can also achieve moisturizing or preservation. Further, the water used in the electrostatic atomizing device 48 is the defrosting water using the refrigerating cooler 24 stored in the water storage container 56, so that the water supply to the water storage container 56 can be automatically performed, so that the water can be omitted. The user (uses the water supply). Since the refrigerating cooler 24 is disposed behind the micro-freezing chamber 14, the defrosting water of the cold cooler 24 near the east chamber 14 can be utilized in the electrostatic atomizing device 48. The water used in the present embodiment is a cold evaporator of the present embodiment, and a double evaporator having two coolers for refrigerating coolers. The ambient temperature of the cooler 25 or the ambient temperature of the cooling 11 of the cooling unit is _phase defrost plus 27 201211480 The heating of the heater becomes a positive temperature of -20 ° C or lower. However, at the time of defrosting There is always a problem in that it is difficult to stably supply water to the observation %, and in this embodiment, the structure of the double evaporator water 4 of the two coolers in the present embodiment is sighed. Placed under the cooling cooling 24 under refrigeration: the cold type of the field In the tank, the refrigeration of the refrigeration cooler 24 of the refrigeration unit 24 will become a negative (mmus) temperature, but still much higher than the temperature of the cold_cooler 25, and = 卩 125 _ but in operation (cold The operation stop of the 1/compressor 27 of the storage compartment of the east temperature section is raised to the vicinity of the machine close to the temperature of the refrigerating compartment 3 by the circulation of the refrigerating blower = therefore, it is provided in the refrigerating cooler 24 The water in the lower water storage container % is hard to freeze, and even if it is frozen, the water is easily supplied to the mist discharge portion 5G. The mist discharge portion 50 of the electrostatic atomization device 48 is oriented differently. A plurality of mist discharge pins (protrusions) 57 that protrude in the direction are formed. With this configuration, unlike the case where the protruding direction of the projection for generating mist is only one direction, the mist 28 201211480 can be set to a plurality of directions. Therefore, the supply range of the mist can be widened.
MqAA A %通過採用所述霧放出銷(突部)57將供 :° 、水平部53&夾在中間而向上下相反方向延伸的結 t從而也可將翻向切與下方_反方向料,可加 寬霧的供給範圍。 而且:供水部53的水平部53a以及祕放出銷57是 以與冷氣導★ 34巾的冷藏用冷卻ϋ室36的前部壁36a成 平行的=式而沿著該前部壁36a而配置,由此可實現前後 方向的薄型化。通過將霧放㈣(突部)57配置成上下兩 段,可實現緊湊(compact)化。 霧放出部5 0通過採用使多個所述霧放出銷(突部)5 7 排列成列狀而配置的結構,可增多霧的放出量,從而可進 一步加寬霧的供給範圍,而且,可實現薄型化。 採用了下述結構,即,供水部53具有彎曲部53c,在 彎曲部53c的下方設有儲存水的儲水容器56,可將儲水容 器56中儲存的水供給至所述彎曲部53c。由此,可將儲水 容器56的水經由彎曲部53c而供給至霧放出銷57。 電源裝置52將霧放出部5〇夾在中間而配置於彎曲部 53c的相反側。由此,可使電源裝置52更加遠離儲水容器 56。 而且,通過將電源裝置52以及霧產生單元51以與冷 氣導管34中的冷藏用冷卻器室36的前部壁36a成平行的 方式而沿著該前部壁36a而配置’可實現靜電霧化裝置48 的縱深方向的薄型化。 29 201211480 將靜電霧化裝置48的霧放出部50中的霧放出銷(突 部)57以沿著冷氣導管34的方式而配置。由此,可抑制 靜電霧化裝置48的前後方向的縱深尺寸,從而可實現薄型 化。伴隨於此,可抑製冰箱内容積的減少。 在冷氣導管34的前部,設有向霧用專用導管45内供 給冷氣的霧用冷氣供給口 62,將靜電霧化裝置48的霧放 出部50配置於所述冷氣導管34的前方。 由此,可利用從霧用冷氣供給口 62供給至霧用專用導 管45内的冷卻風,來使從霧放出部50放出的霧飄散到遠 處。 霧用冷氣供給口 62與霧放出部50 (霧放出銷57)以 與相向的位置不同的方式(以不直接相向的方式)而配置 在左右偏離的位置上,因此從霧用冷氣供給口 62供給至霧 用專用導管45内的冷卻風不會直接吹到霧放出部50 (霧 放出銷57)。 由此,可使霧放出銷57直接受到來自霧用冷氣供給口 62的冷卻風而乾燥的現象受到抑制。 在冰箱本體1中,包括收容具有霧放出部50的靜電霧 化裝置48的霧用專用導管45,在該霧用專用導管45内, 設有使由霧放出部50所產生的霧的供給目標不同的多個 霧吹出口。 多個霧吹出口具體是指冷藏室用霧吹出口 63a、微凍 室用霧吹出口 65、蛋盒用霧吹出口 66及蔬菜室用霧吹出 口 67。 201211480 /由t可將霧用專用導管45内產生的霧供給至冷藏室 3、微康室14、蛋盒15以及蔬菜室4這4個供給目標,可 加寬^供給範m ’從而可擴大霧的效果範圍。 霧的供給目標中的微凍室14、蛋盒15以及蔬菜室4 分別具有微心18、蛋盒15、蔬菜盒(下部盒丨卜上部 盒12),可將霧良好地供給至這些盒内。 此時夕個霧吹出口(冷藏室用霧吹出口 63a、微;束 室用霧吹/口 65、蛋盒用霧吹出口 66和蔬菜室用霧吹出 口 67)疋配置在以霧放出部5()為中心的周圍,因此可將 從霧,出部5G放出的霧良好地供給至各霧吹出口。 ^務產生單元51具有霧放出銷(突部)57,霧用專用導 管45的多個霧吹出σ (冷藏室用霧吹出口 63a、微康室用 霧吹出口 65、蛋盒用霧吹出口 66和蔬菜室用霧吹出口 67) 疋配置在與霧放出銷57相向的位置為不同的位置(不直接 相向的位置)上,因此,即使萬一有手指或異物從霧吹出 口插入霧用專用導管45内’也能防止他們直接接觸霧放出 銷57,從而可確保安全性。 而且’由於形成霧用專用導管45的導管構成構件46 為可裝卸,因此可容㈣進行霧產生單元51等的保養 (maintenance) ° 冷氣導管34具有配置冷藏用冷卻器24的冷藏用冷卻 器室36的前部壁36a (第1突出部)、及位於該前部壁36a 的下方且配置儲水容器56的下部突出部36c (第2突出 部)’向霧用專用導管45内供給風(冷氣)的霧用冷氣供 31 201211480 給口 62設在成為第1突出部的前部壁36a上。 根據此結構,儲水容器56配置在 霧用冷氣供給π 62供給至咖專科f45⑽冷’從 不會供給至儲水容H %,因此儲水容器%⑽存的雑 以蒸發,從而能夠良好地確保霧用的水。 、 成為第2突出部的下部突出部36c以朝向成為第丄 出部的前部壁36a更前方大為突出的方式而設,構成霧放 出機構的靜f霧化裝置48具有將水從儲水容%移送至 霧放出部5G為止的保水材料55,該保水材料55從下部突 出部36c延伸至冷氣導管34外的霧用專用導管45内, 放出部50配置在前部壁3以的前方。 根據此結構,在前部壁36a上形成有向霧用專用導管 45内供給風(冷氣)的霧用冷氣供給口 62,從該霧用冷氣 供給口 62供給至霧用專用導管45内的風不會吹到吸取儲 水容器56的水的保水材料55的下部,因此,尤其能夠防 止.保水材料55的下部因來自霧用冷氣供給口 62的風而 變幹’從而能夠將儲水容器56的水良好地供給至霧放出部 50。並且’由於保水材料55被盒54所覆蓋,因此即使盒 54受到風,保水材料55也難以變幹。 (第2實施方式) 圖12表示第2實施方式。該第2實施方式中,構成除 菌成分產生機構的靜電霧化裝置85中的霧產生單元86的 結構與第1實施方式不同。 霧產生單元86具備霧放出部87以及對該霧放出部87 32 201211480 供、π水刀的供水88。供水部88具有從正 的圓形部88a、以及從該圓形部88a向 :89=:與第1實施方式同樣的保— 下端部貫穿導管構成構件46的下部以及 所述冷Ϊ用冷部益室%的前部的段部36b(參照圖8),並 從上方插人冷藏科卻衫36⑽設_水容ϋ56内 部娜以與冷氣導 ^中的守臧用冷卻器室36的前部壁36a成平 沿著該前部壁36a·置。 針订的方式 B霧^ =7是由分別構成突部的多根霧放出銷57所 務出鎖57呈放射狀地設在圓形部S8a的外周部。 放出是:朝同的方向突出的多個霧 盒沾而與保水觸各減㈣57的底端部貫穿 器室==:是二與冷氣導管34中的冷藏用冷卻 置。 。卩壁36a成平打的方式沿著前部壁36a而配 出的ΐΐΓΓ8中的圓形部88a的左部,設有向左側方突 而設:受電銷8二,在該突出部88。上’以向左突出的狀態 電端t 受電銷58連接於電源裝置52侧的供 通過==,儲水容器56内儲存的水由保水材料90 象而吸取,並供給至各霧放出銷57。而且, 33 201211480 來自電源裝置52的負的高電壓從受電銷58經由保水材料 90的水分而施加至各霧放出銷57,基於此,從各霧放出銷 57放出微細的霧。 從各霧放出銷57放出的霧是與第1實施方式同樣地, 從多個霧吹出口(冷藏室用霧吹出口 63a、微凍室用霧吹 出口 65、蛋盒用霧吹出口 66和蔬菜室用霧吹出口 67)供 給至冷藏室3、微凍室14、蛋盒15以及蔬菜室4等多個供 給目標。 在此種第2實施方式中,尤其由於霧放出銷57是呈放 射狀配置,因此與第1實施方式的情況相比,具有能夠向 更多的方向放出霧的優點。 (第3實施方式) 圖13表示第3實施方式。該第3實施方式中,下述方 面與第1實施方式不同。 在對蔬菜室用霧吹出口 67的上游的通路67b進行縮窄 的通路縮窄壁67a上,呈固定狀態而設有風向板81。該風 向板81進一步縮窄通路67b。 通過設置風向板81,能夠進一步減少從蔬菜室用霧吹 出口 67向蔬菜室4侧吹出的冷氣的量,從而可防止蔬菜室 4的過冷。 (第4實施方式) 圖14表示第4實施方式。該第4實施方式中,下述方 面與第3實施方式不同。 在通路縮窄壁67a中,取代固定狀態的風向板81而可 34 201211480 轉動地設有風向板82 〇通過該風向板82的轉動位置,能 夠改變通路67b的開口面積。 優選通過未圖示的馬達(motor)來控制該風向板82 的轉動位置。借此,也能獲得與第3實施方式同樣的作用 效果。 (第5實施方式) 圖15表示第5實施方式。該第5實施方式中,下述方 面與第1實施方式不同。 在蔬菜室用霧吹出口 67的上方的通路67b中,設有由 電加熱器構成的加熱器83。利用該加熱器83來對通過通 路67b的空氣(冷氣)進行加熱,由此能夠提高從蔬菜室 用霧吹出口 67吹出的空氣的溫度,從而可進一步確實地防 止蔬菜室4的過冷。 (第6實施方式) 圖16表示第6實施方式。該第6實施方式中,下述方 面與第1實施方式不同。 在對冷藏室3與蔬菜室4之間進行分隔的分隔板1〇 内,設有向前後方向(圖16中的左右方向)延伸的延長導 管185 (導管)。該延長導管185為上段導管185a與下段 導管185b的上下兩段’且上段導管i85a與下段導管18% 利用前部的連通部185c而連通。 其中的上段導管185a的後部的上部經由連通口 75而 連通於蔬菜室用霧吹出口 67。在下段導管185b的下表面, 設有多個向蔬菜室4的上部開口的吹出口 186。 35 201211480 在上述結構中,於霧用專用導管45内發生對流的空氣 及霧通過蔬菜室用霧吹出口 67、連通口 75而供給至延長 導管185的上段導管185a。供給至上段導管185a的空氣 及霧如圖16的箭頭C所示,在上段導管185a内朝向前方 流動後,在連通部185c中將方向改為朝下,並在下段導管 185b内朝向後方流動,再從多個吹出口 186吹出至蔬菜室 4内。 在上述實施方式中,從蔬菜室用霧吹出口 67吹出的空 氣及霧在通過延長導管185的過程中溫度逐漸變高,因此 將對蔬菜室4供給溫度相對較高的空氣’由此也能夠防止 蔬菜室4的過冷。 (其他實施方式) 作為除菌成分產生機構,並不限於上述靜電霧化裝 置,例如也可採用下述結構,即,通過對放電電極施加高 電壓而產生離子(ion) ’並將該離子與空氣中的水分結合 而成的成分作為除菌成分而放出。而且,也可採用下述結 構’即,利用電暈放電等來產生臭氧,並將臭氧作為除菌 成分而放出。 進而,也可使用超聲波式霧化裝置,即,通過超聲波 振動元件的超聲波振動來使儲水部中儲存的水霧化並使霧 放出。而且,作為用於吹出從霧放出機構放出的霧的霧吹 出口’也可未具備冷藏室用霧吹出口 63a及蛋盒用霧吹出 〇 66 〇 如上所述,根據本實施方式的冰箱,採用了下述結構, 36 201211480 即,將產生霧的除菌成分產生機構設置於微康室的裏部, 將由該除g成分產生機構職生_自由基或臭 菌成2給至财室,因此_容易地實現儲藏肉或魚^ 的微珠室的除菌或除臭。 ” ,且’根據本實施方式的冰箱,在·通過冷卻器後 的冷氣,毅織㈣料_供給至财室 ΐ箱I,將縣㈣霧吹出口㈣口面觀定為小於微= 室用務吹出口的開口面積。 由此,從蔬菜室用霧吹出口向蔬菜室側吹 氣的量)變得少於從财m以时出至财室2 風量(冷氣的量)。 叉尽至門的 因此’能夠抑制從蔬菜室用霧吹出口向蔬菜室4側吹 出的風量(冷氣的量),從而可防止:蔬菜室因通過 後的冷氣而變得過冷。 以上所述,僅是本發明的較佳實施例而已,並非對本 發明作任何形式上陳制,賴本發明巳讀佳實施例揭 露如^細並非肋限定本發明,任何齡本專業的技 術士員,在不脫離本發明技術方案範圍内,當可利用上述 揭不的,構及技細料岭許的更誠料為等同變化 的等效實關,但是凡是未麟本發明技術方案的内容, 依據本發明的技術實質對以上實施例所作的任何簡單修 改、等同變化與修飾’均仍屬於本發明技術方_範圍. 雖然本發明已以較佳實施例揭露如上,然其並非用以 限定本發明’任何熟習此技藝者,在賴縣發明之精神 37 201211480 和範圍内,當可作些許之更動與潤飾,因此本發明之保護 範圍當視後附之申請專利範圍所界定者為準。 【圖式簡單說明】 圖1是表示第1實施方式的冰箱整體的概略結構的縱 剖侧面圖。 圖2是以除去門或擱板等的狀態來表示的冰箱本體的 正面圖。 圖3是微康室附近的概略的立體圖。 圖4是霧用專用導管周邊的放大正面圖。 圖5是沿著圖4中的XIon線的橫剖平面圖。 圖6是沿著圖4中的X2-X2線的縱剖侧面圖。 圖7是沿著圖4中的X3-X3線的縱剖侧面圖。 圖8是沿著圖4中的X4-X4線的縱剖側面圖。 圖9是冷藏室的下部(微凍室)以及蔬菜室附近的縱 剖正面圖。 圖10是沿著圖9中的X5-X5線的縱剖側面圖。 圖11是靜電霧化裝置部分的縱剖正面圖。 圖12是第2實施方式的相當於圖u的圖。 圖13是第3實施方式的相當於圖u的圖。 圖14是第4實施方式的相當於圖u的圖。 圖15是第5實施方式的相當於圖u的圖。 圖16是第6實施方式的相當於圖j的圖。 【主要元件符號說明】 1 ·冰箱本體 38 201211480 2:隔熱箱體 2a :外箱 2b :内箱 2c、38 :隔熱材料 3 :冷藏室 3a、4a、5a、7a :隔熱門 4 :蔬菜室 5 :製冰室 6 :小冷凍室 7 :冷凍室 8:自動製冰裝置 8a :製冰盒 10 :分隔壁 11 :下部盒 12 :上部盒 13 :搁板 14 :微凍室 15 :蛋盒 16 :小物盒 17 :儲水箱 18 :微凍盒(容器) 18a :前表面壁 18b :切口部 19 :隔熱分隔壁 39 201211480 20 :儲冰容器 22 :儲藏容器 24 :冷藏用冷卻器 25 :冷凍用冷卻器 26 :機械室 27 :壓縮機 28 :除霜水蒸發皿 29 :控制裝置 30 :冷凍用冷卻器室 30a :冷氣吹出口 30b :返回口 31 :冷;東用送風風扇 32 :排水管 34 :冷氣導管 35 :冷藏用送風機 36 :冷藏用冷卻器室 36a :前部壁 36b :段部 36c :下部 37 ··冷氣供給導管 39 :冷氣供給口 40 :排水管 42 :送風導管 43 :吸入口 201211480 45 :霧用專用導管 46 :導管構成構件 48、85 :靜電霧化裝置(霧產生(放出)機構、除菌 成分產生機構) 50、 87 ··霧放出部 51、 86 :霧產生單元 52 :電源裝置 53 :供水部 53a :水平部 53b、88b :垂直部 53c :彎曲部 54、 89 :盒 55、 90 :保水材料 56 :儲水容器(儲水部) 56a :溢水部 57 :霧放出銷 58 :受電銷 60 :導線 61 :供電端子 62 :霧用冷氣供給口 63 :面向冷藏室的霧用導管 63a :冷藏室用霧吹出口 65:微凍室用霧吹出口(吹出口) 66 :蛋盒用霧吹出口 201211480 67 :蔬菜用霧吹出口 67a:通路縮窄壁 67b :通路 68 :微;東室用冷氣供給口 70 :載置板(頂板部) 71a、71b :分隔板 72 :保鮮蓋 73 :通氣路 74a、74b :通氣口(空氣出口) 75 :連通口(空氣出口) 76 : V導管 77 :通氣口 81、82 :風向板 83 :加熱器 88 :供水部 88a :圓形部 88c :突出部 185 :延長導管(導管) 185a :上段導管 185b :下段導管 185c :連通部 186 :吹出口MqAA A % can also use the mist discharge pin (protrusion) 57 to sandwich the center portion of the horizontal portion 53 & and extend in the opposite direction upward and downward so that the turning direction can be reversed and the lower direction is reversed. The supply range of the mist can be widened. Further, the horizontal portion 53a and the secret release pin 57 of the water supply portion 53 are disposed along the front wall 36a in parallel with the front wall 36a of the refrigerating cooling chamber 36 for the cold air guide. Thereby, the thickness in the front-rear direction can be reduced. By arranging the mist (four) (protrusion) 57 in two stages, compactness can be achieved. The mist releasing portion 50 is configured such that a plurality of the mist releasing pins (protrusions) 5 7 are arranged in a line, so that the amount of mist released can be increased, and the supply range of the mist can be further widened. Achieve thinning. The water supply unit 53 has a curved portion 53c, and a water storage container 56 for storing water is provided below the curved portion 53c, and water stored in the water storage container 56 can be supplied to the curved portion 53c. Thereby, the water of the water storage container 56 can be supplied to the mist discharge pin 57 via the curved portion 53c. The power supply unit 52 is disposed on the opposite side of the curved portion 53c with the mist releasing portion 5〇 interposed therebetween. Thereby, the power supply unit 52 can be further moved away from the water storage container 56. Further, by disposing the power supply device 52 and the mist generating unit 51 along the front wall 36a in parallel with the front wall 36a of the refrigerating cooler chamber 36 in the cold air duct 34, electrostatic atomization can be realized. The device 48 is thinned in the depth direction. 29 201211480 The mist discharge pin (protrusion) 57 in the mist discharge portion 50 of the electrostatic atomizing device 48 is disposed along the cold air duct 34. Thereby, the depth dimension of the electrostatic atomization device 48 in the front-rear direction can be suppressed, and the thickness can be reduced. Along with this, the reduction in the internal volume of the refrigerator can be suppressed. In the front portion of the cold air duct 34, a cold air supply port 62 for supplying cold air to the special duct 45 for mist is provided, and the mist discharge unit 50 of the electrostatic atomizing device 48 is disposed in front of the cold air duct 34. Thereby, the cooling air supplied from the mist cold air supply port 62 to the mist dedicated duct 45 can be used to disperse the mist emitted from the mist discharge unit 50 to a distant place. The mist cooling air supply port 62 and the mist releasing portion 50 (the mist releasing pin 57) are disposed at positions shifted to the left and right so as not to face each other in a direction different from the opposing position. Therefore, the cold air supply port 62 for fogging is provided. The cooling air supplied into the special duct 45 for fog is not directly blown to the mist discharge unit 50 (the mist discharge pin 57). Thereby, the phenomenon that the mist discharge pin 57 is directly dried by the cooling air from the mist cold air supply port 62 can be suppressed. The refrigerator main body 1 includes a special duct 45 for mist that houses the electrostatic atomizing device 48 having the mist releasing portion 50, and a supply target for the mist generated by the mist releasing portion 50 is provided in the special duct 45 for mist. Different multiple mist blowing outlets. Specifically, the plurality of mist blowing outlets are a mist blowing outlet 63a for a refrigerating compartment, a mist blowing outlet 65 for a micro-freezing chamber, a mist blowing outlet 66 for an egg box, and a mist blowing port 67 for a vegetable compartment. 201211480 / The mist generated in the special duct 45 for mist can be supplied to the four supply destinations of the refrigerating compartment 3, the micro-compartment 14, the egg box 15, and the vegetable compartment 4 by t, and the supply range m' can be widened to expand The range of effects of the fog. The micro-freezing chamber 14, the egg box 15, and the vegetable compartment 4 in the mist supply target respectively have a micro-heart 18, an egg box 15, and a vegetable box (the lower box 上部 upper box 12), and the mist can be favorably supplied into the boxes. . At this time, the mist blowing outlets (the mist blowing outlet 63a for the refrigerator compartment, the micro-bubble blowing port 65 for the bundle chamber, the mist blowing port 66 for the egg box, and the mist blowing port 67 for the vegetable compartment) are disposed around the mist releasing portion 5 (). Therefore, the mist discharged from the mist and the outlet 5G can be satisfactorily supplied to each of the mist blowing outlets. The service generation unit 51 has a mist discharge pin (projection) 57, and a plurality of mists for the mist dedicated duct 45 are blown out σ (a refrigerator chamber mist outlet 63a, a micro chamber mist outlet 65, an egg box mist outlet 66, and vegetables). The room mist blowing port 67) is disposed at a position different from the position at which the mist releasing pin 57 faces (a position that does not directly face). Therefore, even if a finger or foreign matter is inserted from the mist blowing port into the special duct 45 for the mist' It also prevents them from directly contacting the mist release pin 57, thereby ensuring safety. Further, since the duct constituent member 46 for forming the special duct 45 for mist is detachable, it is possible to carry out the maintenance of the mist generating unit 51 and the like. (The cooling air duct 34 has the refrigerating cooler chamber in which the refrigerating cooler 24 is disposed. The front wall 36a (first protruding portion) of 36 and the lower protruding portion 36c (second protruding portion) ′ disposed below the front wall 36a and disposed in the water storage container 56 supply air into the special duct 45 for fog ( The cold air supply for the cold air supply 31 201211480 The supply port 62 is provided on the front wall 36a which becomes the 1st protrusion part. According to this configuration, the water storage container 56 is disposed in the mist cold air supply π 62 and supplied to the coffee service f45 (10), and the cold storage is never supplied to the water storage capacity H%. Therefore, the water storage container % (10) is stored and evaporated, so that the mist can be surely secured. Used water. The lower protruding portion 36c that is the second protruding portion is provided so as to protrude forward from the front wall 36a that is the first protruding portion, and the static atomizing device 48 that constitutes the mist releasing mechanism has water from the storage capacity. The water retaining material 55 is transferred to the mist releasing portion 5G, and the water retaining material 55 extends from the lower protruding portion 36c to the special duct 45 for the mist outside the cold air duct 34, and the discharging portion 50 is disposed in front of the front wall 3. According to this configuration, the cold air supply port 62 for supplying the wind (cold air) to the inside of the special duct 45 for the mist is formed in the front wall 36a, and the wind is supplied from the mist cold air supply port 62 to the wind in the special duct 45 for mist. Since the lower portion of the water retaining material 55 that sucks the water of the water storage container 56 is not blown, it is particularly possible to prevent the lower portion of the water retaining material 55 from drying out due to the wind from the cold air supply port 62 for the mist, so that the water storage container 56 can be removed. The water is supplied to the mist discharge portion 50 satisfactorily. And since the water retaining material 55 is covered by the case 54, even if the case 54 receives wind, the water retaining material 55 is hard to dry. (Second Embodiment) Fig. 12 shows a second embodiment. In the second embodiment, the configuration of the mist generating unit 86 in the electrostatic atomizing device 85 constituting the sterilization component generating means is different from that of the first embodiment. The mist generating unit 86 includes a mist releasing portion 87 and a water supply 88 for supplying the π water jet to the mist releasing portion 87 32 201211480. The water supply unit 88 has a lower portion from the positive circular portion 88a and the circular portion 88a to the lower portion of the first and second embodiments, and a lower portion of the conduit forming member 46 and the cold portion for cold heading. The front portion 36b of the benefit room % (refer to FIG. 8), and the front part of the cooler chamber 36 for the sluice in the cold air guide is inserted from the upper side of the cold storage section 36 (10) The wall 36a is placed flat along the front wall 36a. The method of stitching B is as follows: a plurality of mist discharge pins 57 respectively constituting the projections are provided, and the lock 57 is radially provided on the outer peripheral portion of the circular portion S8a. The discharge is: a plurality of mist boxes protruding in the same direction and a lower end of the water retaining contact (four) 57. The through-chamber chamber ==: is the cooling device for cooling in the cold air duct 34. . The left side of the circular portion 88a of the crucible 8 which is disposed along the front wall 36a in a manner of being flattened is provided with a power receiving pin 8 provided on the left side of the flange 8a. The upper side electric terminal t is protruded to the left, and the power receiving pin 58 is connected to the side of the power supply device 52 for the passage of ==, and the water stored in the water storage container 56 is sucked by the water retaining material 90 and supplied to the respective mist discharge pins 57. . Further, 33 201211480 The negative high voltage from the power supply unit 52 is applied from the power receiving pin 58 to the respective mist discharge pins 57 via the moisture of the water retaining material 90, whereby fine mist is released from each of the mist discharge pins 57. In the same manner as in the first embodiment, the mist is discharged from the plurality of mist blowing outlets (the refrigerator compartment mist outlet 63a, the microfreezer mist outlet 65, the egg box mist outlet 66, and the vegetable compartment mist). The outlet 67) is supplied to a plurality of supply destinations such as the refrigerating compartment 3, the micro-freezing compartment 14, the egg cartridge 15, and the vegetable compartment 4. In the second embodiment, in particular, since the mist release pin 57 is disposed in a radiating manner, it has an advantage that the mist can be released in a larger direction than in the case of the first embodiment. (Third Embodiment) Fig. 13 shows a third embodiment. In the third embodiment, the following aspects are different from the first embodiment. The air passage plate 81 is provided in a fixed narrowing manner in the passage narrowing wall 67a which narrows the passage 67b upstream of the mist outlet 63 of the vegetable compartment. The wind direction plate 81 further narrows the passage 67b. By providing the wind direction plate 81, the amount of cold air blown from the vegetable chamber mist blowing outlet 67 to the vegetable compartment 4 side can be further reduced, and the vegetable compartment 4 can be prevented from being excessively cooled. (Fourth embodiment) Fig. 14 shows a fourth embodiment. In the fourth embodiment, the following aspects are different from the third embodiment. In the passage narrowing wall 67a, instead of the wind direction plate 81 in the fixed state, the wind direction plate 82 is rotatably provided by the 2012-11480, and the opening position of the passage 67b can be changed by the rotational position of the wind direction plate 82. Preferably, the rotational position of the wind direction plate 82 is controlled by a motor (not shown). Thereby, the same operational effects as those of the third embodiment can be obtained. (Fifth Embodiment) Fig. 15 shows a fifth embodiment. In the fifth embodiment, the following aspects are different from the first embodiment. A heater 83 composed of an electric heater is provided in the passage 67b above the mist outlet 63 of the vegetable compartment. By heating the air (cold air) passing through the passage 67b by the heater 83, the temperature of the air blown from the vegetable chamber mist outlet 67 can be increased, and the supercooling of the vegetable compartment 4 can be further reliably prevented. (Sixth embodiment) Fig. 16 shows a sixth embodiment. In the sixth embodiment, the following aspects are different from the first embodiment. In the partitioning plate 1 that partitions between the refrigerating compartment 3 and the vegetable compartment 4, an extension duct 185 (conduit) extending in the front-rear direction (left-right direction in Fig. 16) is provided. The extension duct 185 is the upper and lower sections of the upper duct 185a and the lower duct 185b, and the upper duct i85a and the lower duct 18% are communicated by the front communicating portion 185c. The upper portion of the rear portion of the upper duct 185a communicates with the vegetable chamber mist outlet 67 via the communication port 75. On the lower surface of the lower duct 185b, a plurality of air outlets 186 opening to the upper portion of the vegetable compartment 4 are provided. In the above configuration, the convection air and mist in the special duct 45 for mist are supplied to the upper duct 185a of the extension duct 185 through the vegetable chamber mist outlet 67 and the communication port 75. As shown by the arrow C in FIG. 16, the air and the mist supplied to the upper duct 185a flow forward in the upper duct 185a, and the direction is changed downward in the communicating portion 185c, and flows backward in the lower duct 185b. Further, it is blown out from the plurality of air outlets 186 into the vegetable compartment 4. In the above-described embodiment, the air and the mist blown from the vegetable chamber by the mist blowing port 67 gradually increase in temperature during the passage of the extension duct 185, so that the vegetable chamber 4 is supplied with a relatively high temperature air'. The vegetable room 4 is too cold. (Other embodiment) The sterilization component generation means is not limited to the above-described electrostatic atomization device. For example, a configuration may be employed in which an ion is generated by applying a high voltage to the discharge electrode and the ion is The components combined with the moisture in the air are released as a sterilization component. Further, the following structure may be employed, i.e., ozone is generated by corona discharge or the like, and ozone is released as a sterilizing component. Further, an ultrasonic atomizing device may be used in which the water stored in the water storage portion is atomized by the ultrasonic vibration of the ultrasonic vibration element to release the mist. Further, the mist outlets for blowing out the mist discharged from the mist discharge means may not include the refrigerator compartment mist outlet 63a and the egg box mist blowing port 66. As described above, the refrigerator according to the present embodiment is used. STRUCTURE, 36 201211480 That is, the sterilizing component generating mechanism that generates the mist is placed in the inner part of the micro-compartment, and the genital _free radical or bacterium is added to the financial office by the genital component. The sterilization or deodorization of the microbead chamber for storing meat or fish is achieved. And, according to the refrigerator of the present embodiment, the air-conditioning after passing through the cooler, the Yi-Wei (four) material _ is supplied to the cash box I, and the county (four) mist-blowing outlet (four) mouth surface is determined to be less than micro = room service blow In this way, the amount of the air blown from the vegetable compartment to the vegetable compartment side is reduced from the time of the money to the amount of air in the chamber 2 (the amount of cold air). It is possible to prevent the amount of air (the amount of cold air) blown from the vegetable chamber with the mist outlet to the vegetable compartment 4 side, thereby preventing the vegetable compartment from being too cold due to the cold air after passing. The above is only the comparison of the present invention. The present invention is not intended to be in any form, and the present invention is not limited to the scope of the present invention, and is not limited to the scope of the present invention. In the above, when the above-mentioned uncovering is utilized, the more desirable material of the technical details is equivalent to the equivalent change, but the content of the technical solution of the present invention is implemented according to the technical essence of the present invention. Any simple example Modifications, equivalent variations and modifications are still within the scope of the invention. The present invention has been disclosed in the preferred embodiments as described above, but it is not intended to limit the invention to anyone skilled in the art. In the scope of the invention, the scope of protection of the present invention is defined by the scope of the appended claims. FIG. 1 is a view showing the first embodiment. Fig. 2 is a front view of the main body of the refrigerator in a state in which the door or the shelf is removed, etc. Fig. 3 is a schematic perspective view of the vicinity of the micro-compartment. Fig. 5 is a cross-sectional plan view taken along the line XIon in Fig. 4. Fig. 6 is a longitudinal sectional side view taken along line X2-X2 in Fig. 4. Fig. 7 is a cross-sectional view along line X2-X2 in Fig. 4. Figure 8 is a longitudinal sectional side view taken along the line X4-X4 in Figure 4. Figure 9 is a longitudinal section of the lower part of the refrigerator compartment (micro-freezing compartment) and the vicinity of the vegetable compartment Fig. 10 is a longitudinal sectional side view taken along line X5-X5 of Fig. 9. Fig. 11 is a vertical cross-sectional front view of a portion of the electrostatic atomization device. Fig. 12 is a view corresponding to Fig. 2 of the second embodiment. Fig. 13 is a view corresponding to Fig. 5 of the third embodiment. Fig. 14 is a fourth embodiment. Fig. 15 is a view corresponding to Fig. 5 of the fifth embodiment. Fig. 16 is a view corresponding to Fig. 6 of the sixth embodiment. [Description of main components] 1. The refrigerator body 38 201211480 2: Insulation box 2a: Outer box 2b: Inner box 2c, 38: Insulation material 3: Refrigeration chambers 3a, 4a, 5a, 7a: Heat-insulated door 4: Vegetable room 5: Ice-making room 6: Small freezer 7: Freezer compartment 8: Automatic ice making apparatus 8a: Ice making box 10: Partition wall 11: Lower box 12: Upper box 13: Shelf 14: Micro-freezing compartment 15: Egg box 16: Small box 17: Water tank 18: Micro-frozen box (container) 18a: front surface wall 18b: notch portion 19: heat-insulating partition wall 39 201211480 20: ice storage container 22: storage container 24: refrigerating cooler 25: refrigerating cooler 26: machine room 27: Compressor 28: defrosting water evaporating dish 29: control device 30: refrigerating cooler chamber 30a: cold air blowing port 30b: return port 31: cold; east air supply fan 32: Water pipe 34: Cold air duct 35: Refrigeration air blower 36: Refrigerator cooler chamber 36a: Front wall 36b: Segment portion 36c: Lower portion 37 · Cold air supply duct 39: Cooling air supply port 40: Drain pipe 42: Air supply duct 43: Suction port 201211480 45 : Special conduit for mist 46 : Catheter constituent members 48 , 85 : Electrostatic atomization device (fog generation (release) mechanism, sterilization component generation mechanism) 50, 87 · · Fog release parts 51, 86 : Fog generation Unit 52: power supply unit 53: water supply unit 53a: horizontal portions 53b, 88b: vertical portion 53c: curved portions 54, 89: boxes 55, 90: water retaining material 56: water storage container (water storage portion) 56a: overflow portion 57: Fog release pin 58: power receiving pin 60: wire 61: power supply terminal 62: mist cooling air supply port 63: mist duct 63a facing the refrigerating compartment: refrigerating compartment mist blowing port 65: micro-frozen room mist blowing port (blowing port) 66 : Egg box with mist blowing outlet 201211480 67 : Vegetable mist blowing outlet 67a: passage narrowing wall 67b: passage 68: micro; east chamber air-conditioning supply port 70: mounting plate (top plate portion) 71a, 71b: partition plate 72: Fresh cover 73: air passage 74a, 74b: vent (air outlet) 75: communication port (air outlet) 76: V-duct 77: vent 81, 82: wind direction plate 83: heater 88: water supply portion 88a: circular portion 88c: projection portion 185: extension duct (catheter) 185a: upper section Conduit 185b: lower section conduit 185c: communication section 186: blowout outlet
Al、A2、B卜 B2、B3、C、C卜 C2 :箭頭 LI、L2 :距離 42Al, A2, B Bu B2, B3, C, C Bu C2: Arrow LI, L2: Distance 42