TW201202644A - Refrigerator - Google Patents

Abstract

A refrigerator is provided, which can let a mist supply target directly supplied with mist be set at several storage chambers. The refrigerator of this embodiment includes a refrigerator body having a storage chamber; a mist generation unit for generating mist; and ducts, installed at the refrigerator body and receiving the mist generation unit. In the ducts, several mist blow-out openings that let the supply targets of mist generated by the mist generation unit be different are installed.

Description

201202644 VI. Description of the Invention: TECHNICAL FIELD OF THE INVENTION Embodiments of the present invention relate to a refrigerator. [Prior Art] In recent years, for example, there has been known a refrigerator having a mist generating mechanism that generates mist jmiSt by electrostatic atomization. The mist generating means is configured to have a projection for generating a mist, and the mist emitted from the projection is supplied to the storage compartment (refrigeration chamber) by the wind generated by the air blowing means (for example, Patent Document 1). [Prior Art Document] [Patent Document 1] Japanese Patent Laid-Open No. Hei. No. 2006-57999. However, in the past, the supply target of the direct supply mist was limited to one place. Further, in the past, for example, when a beverage or a food juice is spilled into the storage chamber and flows into the mist generating device along the shelf or the wall, the mist may be released from the projection for generating the mist for releasing the mist. The mist of the part is released from the pin or the like, and the performance of the mist generating device is lowered, and the cause of mold and odor is caused. Further, if the mist discharged from the mist discharge pin of the discharge portion is supplied to the storage chamber by the flow of the cold air after passing through the cooler, the storage chamber may be excessively cooled or the mist discharge portion may be frozen. SUMMARY OF THE INVENTION Therefore, there is provided a refrigerator capable of providing a plurality of supply targets for direct supply of mist. Further, it is possible to provide a refrigerator which can prevent the spilled beverage or food juice from flowing into the misty product even when a beverage or food juice is spilled in the storage compartment. Further, a refrigerator capable of preventing the storage compartment from being too cold or the fog releasing portion to be frozen green is provided. The refrigerator of the present invention is characterized in that: the refrigerator body comprises: a plurality of odors, a storage compartment; and a cooler is disposed in the refrigerator body to generate cold (four) cold air to the storage compartment (four); The refrigerator generates a wind and generates a wind; the mist generating mechanism has a storage portion that causes the water in the storage portion to be fogged, and a mist generating chamber is disposed in the refrigerator body to receive the mist generating mechanism. The mist generating chamber has a plurality of air supply ports for guiding the wind generated by the air blowing mechanism, and a plurality of mists are supplied to the plurality of storage chambers, and the mist blowing port 'the mist generated by the mist generating mechanism The human mist is supplied to the plurality of storage chambers in such a manner that the supply target of the mist is different. In this way, it is possible to provide a refrigerator in which a storage chamber to which a supply target of a mist is directly supplied is provided as a plurality of storage compartments. The above and other objects, features, and advantages of the present invention will become more apparent from the description of the appended claims. [Embodiment] Hereinafter, a refrigerator according to a plurality of embodiments will be described with reference to the drawings. In the respective embodiments, the same reference numerals are given to the same components, and the description thereof is omitted. Further, the door side as shown in Fig. 1 with respect to the refrigerator body will be described as the front. (First Embodiment) 201202644 A first embodiment is described with reference to Fig. 1 to Fig. 9. A vertically long rectangular box-shaped heat insulating box 2 in which the refrigerator main body 1 is opened on the front surface is shown in Fig. 1 and Fig. 2 Inside, there are a plurality of storage compartments arranged in the vertical direction. Specifically, in the heat insulating box 2, the upper portion is sequentially provided with refrigerating to the 3, 4 dishes 4 as a storage room, and below the left and right sides, ice making to 5 and a small freezer compartment 6 are arranged. There is a freezer compartment 7 below them. Inside the ice making chamber 5, a well-known automatic ice making device 8 is provided (refer to Fig. 1). The heat insulating box 2 basically consists of an outer box 2a made of a steel plate, an inner box 2b made of synthetic resin, and a heat insulating material provided between the outer box 2a and the inner box 2b. Composition. The refrigerating compartment 3 and the vegetable compartment 4 are storage compartments of a refrigerating temperature section (for example, pc to 4 C), and the refrigerating compartment 3 and the vegetable compartment 4 are vertically partitioned by a partition wall 10 made of plastic. In the front surface portion of the refrigerating compartment 3, as shown in Fig. 1, a hinge opening and closing type heat insulating door 3a is provided. In the front surface portion of the vegetable compartment 4, a suction-type heat insulating door is provided. A lower case u constituting the storage container is coupled to the rear surface of the heat insulating door 4a. On the upper rear side of the lower casing 11, an upper casing 12 which is smaller than the lower casing u is provided. & The inside of the refrigerator compartment 3 is divided into a plurality of sections up and down by a plurality of shelves 13 . As shown in Fig. 3, the lowermost portion (the upper portion of the partition wall 10) in the refrigerating chamber 3 is provided with micro on the right side; the chilled chamber 14' is provided on the left side thereof, and the egg 15 and the small box 16 are provided above and below. Further, a tank 17 is provided on their left side. The water storage tank 17 is for storing water supplied to the ice making box 6 201202644 8a of the automatic ice making device 8. In the micro-freezing chamber 14, a micro-freezing box 18 is provided in the inlet and outlet. The microfreezer 14 also constitutes a storage compartment. The temperature of the micro-freezing chamber 14 is preferably 〇. Hey around. The ice making compartment 5, the small freezing compartment 6 and the freezing compartment 7 are all freezing compartments (for example, a storage compartment of -10 ° C to -20 ° (:). Moreover, the vegetable compartment 4 and the ice making compartment 5 and the small freezing compartment 6 As shown in Fig. 1, the heat insulating partition wall 19 is vertically partitioned. The front surface of the ice making chamber 5 is provided with a suction-type heat insulating door 5a. At the rear of the heat insulating door 5a, the ice storage container 2 is connected. In the front surface portion of the small freezer compartment 6, although not shown, a suction type heat insulating door to which a storage container is connected is also provided. The front surface portion of the freezing compartment 7 is also provided with a storage container 22 attached thereto. The heat-insulating door 7a of the draw-out type is not shown in detail in the refrigerator body 1. However, the two coolings are provided with the refrigeration=cold portion 24 and the cooler 25 (4). The cold air that cools the refrigerator compartment 3 and the vegetable compartment 4 is provided in the back part of the refrigerator main body. The freezing cooler 25 generates the cold air for cooling the ice making compartment 5, the small cold-combination chamber 6, and the freezing compartment 7. It is provided on the back side of the refrigerator body 且 and below the refrigerating cooler 24. What is under the refrigerator body i In the back part of the section, there is a machine room 26, although it is not detailed = but the inside of the shirt 26 is provided with a compressor for the above-mentioned cold ring, a condenser (not shown), for crying into the compressor 27 and condensation: Cooling cooling fan (thin) (not shown) and defrosting water evaporating dish 28 201202644 The control device such as a micro computer that is lower than the lower part of the refrigerator body i is not shown in the figure, but the refrigerator body 丨The electronic wire provided is grounded via the outer casing 2a, etc. Uarth) A cooler chamber 30 is provided in the rear surface portion of the cold chamber 7 in the refrigerator main body 1. In the cold; east chiller chamber 3G, a cold phase cooling unit 25, a defrosting heater (not shown), a cooling air supply fan 31 as a blowing means, and the like are provided. The cooling air blowing fan 31 generates air by the air blowing action by the rotation of the fan to circulate the cold air generated by the freezing cooler 25, and is provided above the freezing cooler 25. A cold air outlet 30a is provided in the intermediate portion of the front surface of the freezing cooler chamber 30, and a return port 3〇b is provided in the lower portion. In the above-described configuration, when the cooling blower fan 31 is driven and the cooling cycle is performed, the wind is generated by the air blowing action, and the cold air generated by the freezing cooler 25 is supplied from the cold air outlet 30a to the ice making chamber 5, and the cold is small. The inside of the bundle chamber 6 and the freezing compartment 7 is returned from the return port 3〇b to the circulation in the freezing cooler chamber 3〇. The ice making chamber 5, the small freezing compartment 6, and the freezing compartment 7 are cooled by the cold air. Further, below the freezing cooler 25, a drain pipe 32 for receiving defrosting water at the time of defrosting of the cooler cooler 25 is provided. The defrosted water received by the drain pipe 32 is led to the defrosting water evaporating dish 28 provided in the machine room 26 outside the refrigerator, and partially evaporated by the defrosting water evaporation jbl 28. And 'the rear of the refrigerator compartment 3 in the refrigerator body 1 and the vegetable compartment 4 201202644

The refrigerating air blower fan 35 of the refrigerating coolers 24 and A is provided. V_s34, and as the air blowing mechanism, that is, the rear of the training chamber in the refrigerator main body 1 is the rearmost portion of the lowermost portion (the micro-cooler chamber 36, in which the refrigerator is guided by 6 tubes = - part = The refrigerating device 24 and the cold air duct 34 for refrigerating refrigeration are formed to supply cold air to the refrigerating compartment 3 and to use the fan 35 that is continuously generated by the cold (four) 2 to rotate by the fan. The cold air generated by the air-cooling cooler 24 is used to generate air so as to be cooled by the lower side. The clothes are provided in the refrigerating cooler 24, and the refrigerating cooler chamber 36 is supplied with a conduit-refrigerator cooler= === The cold air is supplied to the lower end portion of the duct f. The scale is composed of the cold storage duct 37 by the cold storage age (four), and the cold air duct is used. The front wall 3 of the cold air chamber 36 is protruded further toward the cold air supply. Further, 'the front wall of the front wall 37 side 24 is provided with a heat insulating material 38 covering the front surface of the refrigerating cooler 24. And/or there are a plurality of cold air supply ports 39 to the cold ports provided in the front portion of the cool air supply duct 37. Slit to 3 in the lower part of the refrigerating cold compartment chamber 36 and below the cold for refrigerating, a drain pipe 4 is provided. The drain pipe (10) receives the defrosting water from the 24 of the device 24. ^令器201202644 The defrosting water received by the drain pipe 40 is also connected to the defrosting water evaporating dish 28 of the outer box of the outer casing 26, similarly to the defrosting water received by the drain pipe 32, and The defrosting water evaporating dish 28 is partially evaporated. The length dimension of the left and right sides of the water pipe 40 and the depth dimension of the front and rear are larger than the length dimension of the left and right sides of the cooling cooling H 24 and the depth dimension of the front and rear, so as to constitute the size of the defrosting water dripping from the cold cooling 1 24 in the whole county. . A ventilation duct 42 is provided behind the vegetable compartment 4. A refrigerating blower fan 35 is provided in the air duct 42. The air supply duct f 42 has a suction port 43' at the lower end portion, and the upper end portion communicates with the cooling cooler chamber 36 (the cold air duct 34) so as to move back to the drain pipe 4 (). The suction port 43 is opened in the vegetable compartment 4. Further, in the left and right corner portions of the rear portion of the partition wall 10 at the bottom, a plurality of communicating π 44 are formed as shown in Fig. 5 (the right-out communicating compartment 3 in Fig. 5 communicates with the vegetable compartment 4 via the communication port 44. The structural towel, when the wind is blown by the wind fan, is mainly composed of the hollow arrow of Fig. 1 and the air in the chamber 4 is sucked from the suction π 43 to be refrigerated, that is, the vegetable is blown out to the duct 42 On the side of the Langmu (10) 35, the air supply duct 36 and the cold air supply unit 36 are blown out to the air duct 42 side, and the duct 34 is blown (the cold air supply port 39 is blown into the refrigerator compartment 3). The air to be blown out into the refrigerating compartment 3 passes through the communication compartment 4, and the most (four) cold-feeding fan 35~. = supply = 201202644 The air supply function of the refrigerating air supply fan 35 is used to perform the wind front shaft cold shaft Γ 3 Λ (10) air The refrigerating cooler 24 cools "= milk, which is supplied to the refrigerating compartment 3 and the vegetable compartment 4, and the refrigerating compartment 3 and the vegetable compartment 4 are cooled to the temperature of the refrigerating temperature section. The refrigerating compartment of the chamber f3^% In front of the money and the Μ Μ ' ' as shown in Figure 2, Figure 4, the right side of the ice 1 is observed from the front On the side, a mist duct constituting the mist generating chamber 45 is detachably provided. - The chamber 45 is also detachably attached to the front wall by the refrigerating cooler to 36 (a) 36a as shown in Figs. 5 to 8 The duct-forming member 46 of the front surface of the shirt is formed by being surrounded by the duct-constituting member 46. At this time, the mist-generating chamber shirt is long in the left-right direction along the front wall 36a, and the depth dimension in the front-rear direction is small, and is formed into a flat rectangular box shape. In the mist generating chamber 45, a domain portion of the electrostatic atomizing device 48 constituting the mist generating device is housed, and the mist producing line is secretly fogged. Next, the electrostatic atomizing device 48 will be described in detail. As shown in FIG. 9, the device 48 includes a mist generating unit 51 (corresponding to a mist generating mechanism) having a mist releasing portion 5, and a power supply device (transformer (for transformer) for applying a negative high voltage to the mist discharging portion 50. In addition to the main body portion, the electrostatic atomizing device 48 includes a water supply portion 53 that supplies water to the mist discharge unit 50. The water supply portion 53 has a horizontal portion 53a extending in the left-right direction, and a slave portion. The right end of the horizontal portion 53a is downward 11 201202644 The water supply unit 53 is formed in an inverted L shape as viewed from the front, and accommodates the water retaining material 55 in a box 54 having a rectangular L-shaped shape and viewed from the front. The portion 53 is a curved portion 53c between the horizontal portion 53a and the vertical portion 53b. The horizontal portion 53a may be provided in a vertical portion or a different portion from the vertical portion 53b. The horizontal portion ... and the vertical portion may be plated. The front wall panel of the refrigerating cooler chamber of the cold air duct 34+ is disposed in a parallel manner along the front wall 36a. The water retaining material 55 constitutes a water supply member which is suctioned by the capillary phenomenon H 56 (4) water (defrost water) is supplied, and the water retaining material 55 is, for example, wound in a fiber shape, and is excellent in water absorption and water retention. The water-retaining material Η may be a continuous foam, in addition to the above materials, as long as it is excellent in water absorption (four) and maintenance, and can perform capillary action. The lower end portion of the vertical portion 5 of the horizontal portion 53a of the water supply portion 53 which is placed in the mist generating chamber 45 passes through the conduit forming member and/or as shown in Fig. 8 . The front portion 36b of the chiller and refrigerating cooler chamber 36 is located in front of the lower portion in the cold chiller chamber 36. The outer periphery of the water retaining material 55 is covered by the case 54. In water retention materialsΜ

2, it is also possible to constitute a portion of the horizontal portion 53a and a member of the vertical portion. U „ The lower part of the inside of the cooler chamber 36 is provided with a configuration == a granulator 56 (see _). The water storage container 56 is provided between the portion 24 and the drain pipe 40 and below the water supply portion. 12 201202644 Further, the front portion of the water storage container 56 is attached to the lower protruding portion 36c of the front wall 36a of the refrigerating cooler chamber 36, and is provided in a cantilever state that protrudes rearward. At this time, the lower protruding portion 36c to which the front portion of the water storage container 56 is attached is located below the front wall 36a, and protrudes (projects) toward the front wall 36a via the segment portion 36b. When the front wall portion 36a is the first protruding portion, the lower protruding portion 36c is a second protruding portion that protrudes further forward. The water storage container 56 is separated from the refrigerating cooler 24 and the inner box 2b forming the rear surface of the refrigerating cooler chamber 36 in the mounted state of being attached to the lower protruding portion 36c. The refrigerating cooler 24 is in contact with the inner box 2b which forms the rear side of the refrigerating cooler chamber. The lower end portion of the vertical portion 53b of the water supply portion 53 passes through the lower portion of the duct constituting member 46 and the refrigerating cooler chamber 36. The hole formed by the #36 portion 36b of P is inserted into the water storage container % from above. The water storage container 56 receives the defrosted water dripped from the refrigerating cooler 24 and f stores it. 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 S6 by the capillary phenomenon and supplies it to the mist discharge unit 5G. In this way, the defrosted water of the refrigerating device 24 stored in the water container 56 is used for the water supplied to the mist discharge portion, so that the water supply to the water storage container 56 can be automatically performed, and the user can save the water supply. time. The water storage container 56 is located above the height at which the drain pipe 40 can store water. The front end portion of the rear side of the ^ is formed such that the height direction is set to: 7 the lower overflow portion 56a of the wall around the grain 56. Thus, when the water stored in the water storage container 56 overflows, it will overflow from the water 13 201202644. The water overflowing from the overflow portion 56a is discharged to the defrost water evaporating dish 28 by the drain pipe. 40 undertakes,

The portion 56a overflows. The horizontal portion 53a of the water supply unit 53 is disposed on the upper side of the horizontal portion 53a so as to protrude from the plurality of mist release pins 57_, and the four pins are arranged in a horizontal direction in the left-right direction. Configured separately. Further, the other plurality of mist releasing pins are disposed on the lower side of the horizontal portion 53a so as to protrude downward. In this case, the four pins are arranged in a horizontal row in the horizontal direction and are arranged to be spaced apart from each other. The discharge portion 50 is configured to face a different direction, and in this case, a plurality of mist discharge pins 57 projecting in the upward direction. Further, the mist discharge portion 5 is disposed such that the plurality of mist discharge pins 57 are horizontal to the water supply portion 53. The portion 53a is interposed in the middle and extends in the opposite direction. In this configuration, the projection direction of the mist release pin 57, which is the projection for generating the mist, is different only in the unidirectional direction, and the supply direction of the mist can be set to be plural. In the direction, the supply range of the mist can be widened. Further, the plurality of mist discharge pins 57 are arranged in two upper and lower stages. Each of the mist discharge pins 7 is aligned with the front wall 36 of the refrigerating cooler chamber 36 in the cold air duct 34. The mist releasing portion 50 is disposed in the lower portion of the lower portion of the refrigerating chamber 3 and adjacent to the vegetable chamber 4, and is disposed rearward of the micro-chamber 14. Each of the mist releasing pins 57 is as described above. The portion that produces fog as described, for example The 201202644 polyester fiber and the carbon (carb〇n) fiber of the conductive material are twisted and combined to form a (bar shape), which has water retention property and water pumping property and is electrically conductive. The release pin 57 carries a nano choroid. The molybdenum nanocolloid can be obtained, for example, by immersing the rider 57 into a treatment liquid containing colloidal colloid and calcining it. ^ Each mist discharge pin 57 The bottom end portion of the water supply portion 53 passes through the case 54 of the water supply portion 53 and contacts the water retaining material 55. At the left end portion of the horizontal portion of the water supply portion 53, a power receiving pin 58 constituting a receiving electrode is provided to protrude leftward. The end portion contacts the water retaining material 55 in the case 54. The f source device 52 is disposed in the mist generating chamber 45 on the left side of the mist generating unit 51: the right end portion of the power source device 52, and is provided with a wire 6〇 connected thereto and tightened by a, /Lsten) (flat type) terminal constituted by the power supply terminal 61, the power supply terminal idler i generates a power receiving pin 58 of the single turn 51. The power supply device 52 is as public; the pressure is changed " pressure = 5 = frequency power supply ( AC power) is converted to DC as a whole ~ electric boost circuit, etc., generating a negative high voltage (example And outputted to the power receiving pin 58 via the power supply terminal 61. 2 'The negative high voltage from the power supply device 52 is added from the power receiving pin % to the respective mist discharge pin 57 by the discharge pin 57^5 minus 5 ^ moisture (10), so that each mist 55 ^ This is a method of setting up a towel in the Jinghe area. The fog of the water-retaining material is released, and the water is discharged from the water. The water is supplied to each of the mist release pins 57. 15 201202644 At this time, the electric charge is concentrated on the tip end portion of each of the mist release pins 57, and the energy exceeding the surface tension is imparted by the water contained in the tip end portion, so that the water at the tip end portion of the mist release pin 57 is generated. Split (Rays split, fission) 'and emits a fine mist from the front end (electrostatic atomization phenomenon). Here, the water particles discharged in a mist form are negatively charged and contain a radical radical generated by the energy. 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 counter electrode corresponding to the negatively-charged mist discharge pin 57 is not provided. Therefore, the discharge from the mist discharge pin 57 itself becomes very gentle, and no corona discharge is generated between the discharge electrode and the opposite electrode, thereby suppressing harmful gas (ozone) or Ozone produces nitrogen oxides, nitrous acid, nitric acid, etc., which are produced by oxidation of nitrogen in the air. ^The fog release pin 57 (the mist release part 5〇) can be called a release component for releasing a hydroxyl radical/a sterilization component (also a deodorization component) (also a deodorization component discharge mechanism), and static electricity. The atomizing device 48 can be referred to as a sterilization component generating mechanism (deodorizing component generating mechanism). Next, the mist generating chamber 45 will be described in detail. As described above, the mist generating chamber 45 houses the mist generating unit 51 therein. The mist generated by the driving of the mist generating unit 51 is likely to accumulate in the mist generating chamber 45. The fog generated by 51 passes through the generated mist due to the fog, so that even if the density unevenness occurs due to the fog generating unit, the inside of the room 45 is diffused, so that the mist is generated in the chamber 45. The concentration of the mist tends to become substantially uniform. The mist generating chamber 45 has a cold air supply port 62 for the front wall 36a of the refrigerating cooler chamber 36 constituting the rear wall (see Figs. 4 and 7). The mist cooling air supply port 62 is an opening for introducing a part of the wind passing through the refrigerating cooler chamber 36 in the wind generated by the air blowing action of the refrigerating air blowing fan 35 into the mist generating chamber 45 (the flow of the wind is as shown in the figure) 4. Arrow A1 of Fig. 7). Therefore, the mist generating chamber 45 is provided with an opening for introducing the wind that does not pass through the refrigerating cooler chamber 36. In the following, the cold air supply port 62 for mist shown in FIG. 11 is a position (a position that does not face) that is different from the position of the mist discharge pin 57 in the mist discharge unit 50. In this case, the mist discharge unit 50 is present. Further to the left, it is provided above the power supply unit 52 and above the refrigerating cooler 24. As shown in Fig. 7, the mist cooling air supply port 62 penetrates the heat insulating material 38 at the rear portion and communicates with the refrigerating cooler chamber 36 in the cold air duct 34, and the front portion communicates with the mist generating chamber 45. As a result, a part of the cold air (wind) that has passed through the refrigerating cooler chamber 36 is supplied from the mist cold air supply port 62 to the mist generating chamber 45 (see an arrow A1 in Fig. 7). The cold air supplied from the mist cooling air supply port 62 to the mist generating chamber 45 forms convection in the mist generating chamber 45. Further, the mist generating chamber 45 has a plurality of mist blowing outlets, that is, a refrigerator chamber mist blowing port 64, and a micro-freezing chamber mist blowing port, corresponding to the plurality of storage chambers (refrigure chamber 3, micro-freezing chamber 14, egg box 15, and vegetable compartment 4). 65, egg box blown out with fog 17

20120264J mouth 66 and vegetable room with a mist outlet 67. The positions where the mist blowing ports 64, 65, 66, and 67 are provided are different from the positions facing the cold air supply port 62 for fog, that is, the positions directly facing the cold air supply port 62 for fog, and they are set in the mist. The periphery of the unit 51 is for supplying mist to each storage compartment. The refrigerating compartment mist outlet 64 is an opening provided at a lower end portion of the mist duct 63 (see FIGS. 4 and 7 ) facing the refrigerating chamber above the mist cold air supply port 62 , and is located above the mist cold air supply port 62 and It is provided at a position that does not directly face the mist discharge pin 57. In other words, the refrigerating compartment mist blowing port 64 and the mist releasing pin 57 do not face each other in the front-rear direction. The mist duct 63 facing the refrigerating compartment is located on the back side of the front wall 36a of the refrigerating cooler chamber 36, and extends upward. The upper end portion of the mist duct 63 facing the refrigerating compartment communicates with the inside of the cold air supply duct 37 in the cold air duct 34. As a result, the cold air introduced from the mist cooling air supply port 62 is blown to the inner peripheral wall of the mist generating chamber 45 (the back surface of the duct constituent member 46) to change the direction, and a part of the cold air is blown out from the refrigerating chamber by the mist blowing port 64. Therefore, the mist generated by the mist generating unit 51 in the mist generating chamber 45 is easily convected by the cold air introduced from the mist cold air supply port 62 to be diffused. Thereby, the concentration of the mist in the mist generating chamber 45 is more likely to become more uniform. In addition, a part of the convective mist formed in the mist generating chamber 45 passes through the refrigerating compartment mist blowing port 64, the mist duct 63 facing the refrigerating compartment, and the cold air supply duct 201202644, together with a part of the cold air introduced from the mist cold air supply port 62. The cold air supply port 39 is supplied to the refrigerating compartment 3 (the flow of the wind is as indicated by an arrow B1 in Figs. 4 and 7). As shown in FIG. 4 and FIG. 7, the micro-freezing chamber mist blowing port 65 is provided at the front surface portion of the duct constituent member 46 and above the mist cold air supply port 62, and is disposed at a position that does not face the mist discharge pin 57, and is microscopically The freezing chamber 14 is in communication. In other words, the micro-freezing chamber mist blowing port 65 and the mist releasing pin 57 do not face each other in the front-rear direction. Thus, the cold air introduced from the mist cooling air supply port 62 is blown to the inner peripheral wall of the mist generating chamber 45 (the rear surface of the duct constituting member 46) to change the direction. A part of the cold air is blown out from the mist blowing port 65 for the microbeam chamber. Therefore, a part of the mist which forms a convection in the mist generating chamber 45 is supplied to the microbeam chamber 14 from the micro-freezing chamber with the mist blowing outlet 65 together with a part of the cold air introduced from the mist cold air supply port 62 (the flow of the wind is as shown in Fig. 4). , shown by arrow B2 in Fig. 7). As shown in Fig. 4, the egg cartridge mist outlet 66 is provided on the left side of the cold air supply port 62 for the mist in the duct constituent member 46, and is disposed at a position that does not face the mist discharge pin 57, and communicates with the egg box 15. In other words, the egg cartridge mist outlet 66 and the mist discharge pin 57 do not face each other in the front-rear direction. In this way, the air supply from the mist is supplied to the inner peripheral wall of the air conditioning unit 45 (the back surface of the duct component %), and a part of the direction wind is changed from the egg box. Blow it out. The μ spot is formed from the above-mentioned mist in the living chamber 45 - part of the cold air - part introduced by jit 62 - the same as the egg - which is supplied by the fog π 66 to the egg box i shown by the arrow B3). Figure 4 201202644 -----X- 1 2 2 with a fog blowout port 67 as shown in Figure 4, Figure 5, in the fog generation room is set in the "in other words" in the fog for cold air supply The mouth 62 is further to the right, and is connected to the position where the vegetable outlet 57 is in the same position, and is connected to the upper side by the connection σ 44, and the 'fog outlet 67 and the mist release pin 57 are supplied to the front and rear 45. The person blew to the mist generating chamber (the back of the catheter constituting member 46) to change direction, one of the winds. P points are blown out from the vegetable room with a mist blowing Q 67. 2 〃 〃 诚 诚 诚 诚 诚 诚 诚 诚 诚 诚 诚 诚 诚 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 . In addition, the distance L1 between the mist cold air supply port 62 into which the cold air is blown into the mist generating chamber 45 and the vegetable to mist blowing port is set to be larger than the mist cold air supply port 62 and the microfreezer mist blowing port 65. The distance L2. Located above the mist generating chamber 45 and above the mist releasing portion 50, a small freezing chamber air supply duct 68 is provided (see Figs. 4, 6, and 8). As shown in Fig. 8, the micro-freezer air supply duct 68 communicates with the refrigerating cooler chamber 36 through the heat insulating material 38 at the rear portion, and the front portion penetrates the mist generating chamber 45 to communicate with the freezing chamber 14. Therefore, a part of the wind passing through the refrigerating cooler chamber 36, that is, a part of the cold air is directly supplied to the micro-freezing chamber 14 through the air supply duct 68 of the micro-freezing chamber (the wind's movement is as shown in Figs. 6 and 8). As shown by A2) 'With the cold air, the temperature of the freezing chamber I4 is maintained to the left and right. 7 Next, the effect of the refrigerator having the structure of the mist generating mechanism described above is described in 201202,026. The cold air cooled by the cooler 24 in the refrigerating compartment 3 and the vegetable compartment 4 passes through the cold air (wind) generated by the refrigeration for cold storage, mainly by the air supply duct of the fan 35 as shown in FIG. 37 continued to succumb to the room 3 shown in the head. . The external supply is supplied to the refrigerator. Further, the delivery chamber 68 of the refrigerating air supply fan 35 directly escapes the arrow A2) from the micro-8. (Refer to FIG. 6 and the storage of the stored items such as the refrigerating chamber 3 and the freezing chamber 14 after cooling, and then the food is supplied to the vegetable compartment 4. 44 (#m®5)^ Cooling ==3:= A part of the wind of the cold-storage unit 36 is different from the position of the cold air supply port 62 of the mist by the introduction of the mist/gas: the supply port 62 and the supply of the mist to the mist. Because of the position, the wind stalks introduced from the mouth 62 are cold-rolled for the Du 46. The inner peripheral wall of the mist generating chamber 45 (construction structure, body surface) changes direction 'from cold air for fog Supply =: The chamber is blown out of the chamber with a mist, and the mist is blown out by the fog. The fruit outlet is 66, and the vegetable chamber is blown out by the mist blowing outlet 67. Egg 21 201202644 A. At this time, when the electrostatic atomizing device 48 is driven, the fog is emitted. The plurality of mist discharge pins 57 of the generating unit 51 emit fine mist containing hydroxyl radicals as described above. The released mist is accumulated in the mist generating chamber 45 and diffused in the mist generating chamber, and the mist in the mist generating chamber 45 The concentration becomes substantially uniform. Further, by introducing air from the mist cold air supply port 62 into the mist generating chamber 45, mist is generated. The mist in the chamber 45 is diffused and convectively formed, and the concentration of the mist is more uniform. Further, a part of the mist which is convective and has a substantially uniform concentration is passed from the refrigerating compartment mist outlet 64 to the mist duct 63 facing the refrigerating compartment, and The cold air supply duct 37 is supplied to the refrigerating compartment 3, and is supplied from the micro-freezing compartment to the micro-freezing compartment 14 by the mist blowing outlet 65, and is supplied from the egg cartridge mist outlet 66 to the egg carton 15, and the vegetable compartment mist-blowing outlet 67 is connected to the vegetable compartment. 44 is supplied to the vegetable compartment 4 (shown by arrows B2 and B3 in Fig. 4). According to the first embodiment described above, the following effects can be obtained. The refrigerator main body 1 is provided with mist generation to the electrostatic atomization device 48. The mist generating chamber 45 in which the unit 51 (fog generating means) is housed, and the mist generating chamber 45 is provided with a plurality of different supply targets for the mist generated by the mist releasing unit 50 in the mist generating unit 51. The mist blowing outlets are specifically the mist blowing outlets 64 for the refrigerator compartment, the mist blowing outlets 65 for the freezing chambers, the mist blowing outlets 66 for the egg cartridges, and the mist blowing outlets 67 for the vegetable compartments. The raw mist is supplied to the four supply targets of the refrigerating compartment 3, the micro-freezing compartment 14, the eggton 15 and the vegetable compartment 4, and the supply range of the mist can be widened, thereby expanding the range of the effect of the mist. 22 201202644 Waiting, the fog will be well Supply to these, for example, can be used to ensure the effect of deodorization, and it is also expected that the vegetable is additionally used in the mist generation unit 51 in the mist generation. Therefore, the mist generation unit generates The mist is likely to accumulate in the mist production, and the mist generated by the mist generating unit 51 is not diffused in the fog = i is generated in the mist generating chamber 45, so that the degree of fog in the mist generating chamber 45 is still a It is uniform, so that the concentration of the refrigerator compartment can be approximately 56 feet, the micro-freezer blower outlet 65, the egg 2 second withdrawal: ί6, and the vegetable compartment outlet 67 are supplied to the storage compartment (refrigerator compartment 3, 4, egg box 15 and vegetable room 4). At this time, a plurality of mist blowing outlets, such as a mist blowing outlet 64, a mist blowing outlet for the micro chamber, and a mist blowing port 67 for the vegetable compartment, are disposed in a good supply of mu. The mist released by the discharge unit 5 is provided in the position where the fog is blown out by π 64, 65, 66, 67 and is not in the position opposite to the cold heading 62 of the mist, that is, it is not provided for the supply of the cold air. I is in the opposite position, and the mist generating chamber 45 _ mist is diffused in the mist generating chamber 45 by the wind leading from 62, whereby the concentration of the mist in the mist generating chamber 45 becomes more uniform, thereby 23 201202644^ The mist of the uniform concentration can be supplied from the refrigerator compartment mist outlet 64, the micro-chamber mist outlet 65, the egg box mist outlet 66, and the vegetable compartment mist outlet 67 to the storage compartment. Since the mist blowing ports 64, 65, 66, 67 are disposed so that the mist generating unit 51 is around the towel, the mist discharged from the mist generating unit 51 is easily diffused uniformly in the mist generating chamber 45. Thereby, the concentration of the mist in the mist generating chamber 45 can be made more uniform. The plurality of mist blowing outlets of the mist generating chamber 45 (the mist blowing outlet for the refrigerator compartment = micro, the mist blowing outlet 65 for the east chamber, the mist blowing outlet 66 for the egg box, and the vegetable to mist blowing outlet 67) are provided in the mist releasing pin 57. The position where the position is different, that is, the position which is not directly opposed to the mist discharge pin 57, is prevented even if a finger or a foreign object is inserted into the mist generating chamber 45 from the mist blowing outlets 64, 65, 66, and Μ. A finger or foreign matter directly contacts the mist discharge pin 57, thereby ensuring safety. > Since the mist cooling air supply port 62 and the mist releasing portion 50 (the mist releasing pin 57) are provided at positions different from each other, the wind in the mist generating chamber 45 is guided from the cold air supply port 62 (cooling wind) When the mist discharge portion 5G (the mist discharge pin 57) β is not directly blown, the mist release pin 57 can be directly subjected to the cooling wind from the mist gas supply π 62, and the knot can be suppressed. The electrostatic atomizing device 48 constituting the mist generating device includes a mist releasing portion 50 that emits mist, a water supplying portion 53 that supplies water to the mist releasing portion 5, and a power source device 52 that applies a negative voltage to the mist releasing portion 50, and further causes fogging. The discharge portion 50 is composed of a plurality of mist discharge pins 57 that protrude in different directions. 24 201202644 4 This structure is different from the case where the protruding direction of the mist generating projection is only the grass direction. The supply direction of the mist can be set to a plurality of directions, so that the supply range of the mist can be widened. The mist releasing portion 50 is configured by arranging a plurality of mist releasing pins (protrusions) 57 in a row, thereby increasing the amount of mist released, and increasing the supply range of the mist by a small amount of the mist. Thin. Further, the mist releasing portion 50 is configured to extend in the vertically opposite direction by sandwiching the mist releasing pin 57 between the horizontal portions 53a of the water supply portion 53, so that mist can be released from both upward and downward, so that the mist can be further widened. The scope of supply. In addition, since a plurality of storage compartments are provided in the up-and-down direction, the mist Yansheng 45 has a refrigerating compartment mist blowing port 64 corresponding to each storage compartment, a micro-frozen chamber mist blowing outlet 65, an egg box mist blowing outlet 66, and a vegetable compartment. With the configuration of the mist σ human outlet 67, the distance between each storage chamber and the mist discharge lock 57 can be shortened as much as possible, and the mist in the mist generation chamber 45 can be efficiently supplied to each storage chamber. Further, the horizontal portion 53a of the water supply portion 53 and the respective mist release locks 57 are disposed along the front wall 36a so as to be parallel to the front wall 36a of the refrigerating cooler chamber 36 in the cold air duct 34, It can achieve thinning in the front and rear direction. By arranging the mist discharge pin 57 in two upper and lower sections, compactness can be achieved. In the refrigerator main body 1, a cold air duct 34 for supplying cold air to the refrigerating compartment 3 and the vegetable compartment 4 is provided, and the mist generating chamber 45 is disposed along the front wall 36a of the refrigerating cooler chamber 36 in the cold air duct 34. Thereby, the thinning of the mist chamber 25 201202644α can be realized. Further, by arranging the power supply unit 52 and the mist generating unit & 51 along the front wall 36a in parallel with the front wall 3 of the refrigerating cooler chamber 36 of the cold air duct 34+, it is possible to realize The electrostatic atomization device is made thinner in the depth direction. * The water supply unit 53 has a structure in which the water supply portion 53 has a water storage container % for storing water below the female curved portion 53c, and water stored in the water container 56 can be supplied to the curved portion 5 Hey. Thereby, the water of the water storage container 56 can be supplied to the mist discharge pin 57 via the curved portion 53c. Moreover, since the mist discharge lock 57 can be moved away from the water storage container 56, the mist discharge pin 57 can be insulated from the water in the water storage container %. 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 device brother can be further moved away from the water storage container 56°. The water supplied to the mist discharge pin 57 can utilize the defrosting water of the refrigeration cooler 24 stored in the water storage container 56, so that the water can be automatically stored. The water supply to the container 56 saves the user's effort in supplying water. Since the mist generating chamber 45 is formed by the front wall 36a and the detachably mounted duct constituent member 46, the maintenance of the mist generating chamber 45 can be facilitated by detaching the duct constituting member 46. Since 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 differently from the opposing vertical standings, they are supplied from the mist cold air supply port 62 to the mist generating chamber. The cold air in the 45 is not 26 201202644 Thereby, the cooling air of the mist 62 can be dried and released, and the lock 5G can be directly suppressed by the dry air supply from the mist.

It will blow directly to the fog release section 5 (fog release pin 57). Thereby, it is possible to prevent the water retaining material 55 from being dried by the cold air supplied from the mist cold air supply port to the mist generating chamber 45 as much as possible. (Second Embodiment) A second embodiment will be described with reference to Figs. 10 to 12 . The refrigerator main body of the second embodiment has a first path member 71 that forms a cooling path 71a and a second path member 72 that forms a non-cooling path 72a, as shown in Fig. u. The cooling path 71a is a space in which the refrigerating cooler 24 is housed in the refrigerating cooler chamber 36. The wind passing through the cooling path 71a is cooled by the refrigerating cooler 24. At this time, the first path member 71 is a rear portion of the inner case 2b that forms the refrigerating cooler chamber 36 and the heat insulating material 73 to be described later. The non-cooling path 72a is a space for the wind generated by the air blowing action of the refrigerating blower fan 35 to be sent to the mist generating chamber 45 without passing through the refrigerating cooler 24, and is not stored in the refrigerating cooler chamber 36. Use the space of the cooler 24. 27 201202644 The wind passing through the non-cooling path 72a is not directly cooled by the refrigerating cooler 24 because it is not inside. Thus, the 2-way 彳k member 72 is the front wall 36a and the front portion of the heat insulating material 73. The heat insulating material 73 corresponds to the heat insulating material % of the i-th embodiment. The spacer material 73 extends to the lower portion of the heat insulating material of the first embodiment, and extends to the lower portion of the refrigerating cooler 24. Further, the heat insulating material has a portion in the thickness direction on the side of the mist generating chamber 45, and a slit is formed in a portion of the front portion. The shape of the slit is used to form the non-cooling path 72a, and the longitudinal direction = the lower end of the material 73 extends to the vicinity of the end of the uppermost mist discharge pin $ (refer to Fig. U). The left-right direction of the cut 0 is arbitrary, but it is preferable to accommodate the range of the entire lateral direction of the root mist discharge pin 57. The generation chamber 45 has the same cold air supply port 62 and air supply port 74 as the mist cold air supply port of the first embodiment (see FIG. 1A to FIG. 12, the air outlet 74 is for use of the refrigeration fan for refrigeration). The wind in the air supply is introduced into the mist generating chamber 45 by the wind passing through the non-cooling path 72a (the flow of the wind is shown in the arrow c of the u, the air supply port 74 of the 〇3 is provided at the front wall. In the second embodiment, the air supply port 74 is provided with the air supply port 74 as the air supply port, and the lower air supply port is indicated as two, j: the air supply port 74a is located at the position of 36a. It is located above the water transfer 53a (4) The lungs are discharged. The other air supply port 74b is located behind the fog 57 placed under the horizontal portion. 28 In other words, the refrigerator body 1 is viewed from the front, and the air supply port 74a on the upper side is The mist release pin 57 provided above the horizontal portion 53a is located at the overlapping position, and the lower air supply port 74b is located at a position where the mist release pin 57 provided below the horizontal portion 53a is overlapped. According to the configuration of the second embodiment, the refrigeration is performed. Wind generated by the air blowing action of the blower fan 35 The wind passing through the cooling path 7U is cooled by the refrigerating cooler 24 in the cooling path 71a. A part of the cooled wind white is introduced into the mist generating chamber 45 from the mist cold air supply port 62. The cold air supply port for mist 62 and the mist releasing portion 50 (the mist releasing pin 57) are located at positions different from the opposing positions (positions that do not face each other), and therefore are supplied from the mist cooling air supply port 62 to the mist generating chamber 45. The cooling air is not directly blown. The mist discharge portion 50 (the mist discharge pin 57).

The storage room is supplied with a mist outlet 64 and a micro port 66 to each storage room. The wind introduced from the air supply port 74a (see FIG. 1A) is easily blown to the horizontal portion 57' of the mist release pin 57, and is blown out from the cold micro-freezing chamber in the vicinity of the mist release pin 57. The box is blown out by the mist 29 201202644, and the wind introduced from the air supply port 74b (refer to the arrow C3 shown in FIG. 1A and FIG. 2) is easily blown to the mist release pin 57' under the horizontal portion... The vegetable compartment located near the mist discharge pin 57 is supplied to the vegetable compartment 4 by the mist outlet 67. Thereby, the mist having a high concentration which is generated by the mist release pin 57 and existing in the vicinity of the mist discharge pin 57 can be easily convected, and the concentration of the mist in the mist generation chamber 45 can be easily distributed in a high state. It is possible to supply the mist having a high degree of homogenization and a substantially uniform concentration from the respective mist blowing outlets 64, 65, 66, 67 to the storage compartment. The wind blown to the mist discharge pin 57 is supplied to each of the storage compartments from the respective mist blowing ports 64, 65, 66, and 67 in the vicinity of the mist discharge pin 57. Thereby, the mist in the mist generating chamber 45 can be efficiently supplied to each storage chamber. Since the wind is introduced into the mist generating chamber 45 from the air supply ports for the plurality of mists (the cold air supply port 62 for the mist and the air supply ports 74a and 74b in the second embodiment), the flow of the wind in the mist generating chamber 45 is easy. It becomes complicated, so that the concentration of the mist in the mist generating chamber can be made more uniform. In the second embodiment, the wind for supplying the mist discharged from the mist discharge unit 5 to each of the storage compartments is used before passing through the refrigerating cooler 24 in the air circulated by the refrigerating blower 35. That is, the relatively warm air before cooling by the refrigerating cooler 24 is different from the case where the air having a relatively low temperature after passing through the refrigerating cooler 24 can be prevented: the storage compartment, especially the vegetable compartment 4 It becomes too cold due to the air used to supply the mist. Further, as described above, the air (wind) supplied to the mist discharge pin 50 is 201202644 before and after passing through the refrigerating cooler 24, that is, the air before, so that the cooling device 24 can be prevented from being cooled. In order to prevent the mist release pin 50 from being frozen, the cold pin 5 is frozen by the cold air supply port. The purpose 'can also eliminate the fog, and the mist release pin 50 is disposed outside the cold air duct 34. The mist is discharged from the mist (4) and the cooling device 24 is used to cool the H 24 , so that the mist can be stopped. In the second embodiment, it is supplied to the first embodiment, and the second embodiment is used for the cold air or the wind supplied to the mist generating chamber 45 in the first embodiment and the third embodiment. Side =:==: However, as described above, the mist generating chamber is supplied. (Third Embodiment) A third embodiment will be described with reference to Figs. 13 to 15 . As shown in FIG. 14, the refrigerator main body i of the third embodiment includes the i-th path members 71 and the second cooling passages 71a of the second embodiment, and the non-cooling paths 72 and (see) of the second embodiment. (1) The second path member 82 of the non-cooling path 82a of a different shape. The non-cooling path 82a is a space for sending the wind generated by the refrigerating riding fan % to the enchantment room 45 without passing through the cooling chiller 24, It is a space in which the refrigerating cooler 24 is not accommodated in the refrigerating cooler chamber 36. * The air (wind) passing through the non-cooling path 82a does not accommodate the refrigerating cooler 24, and therefore does not pass through the refrigerating cooler 24 The second path member 82 is a front wall 36a and a heat insulating material 83. 31 201202644 The heat insulating material 83 corresponds to the heat insulating material of the second embodiment. The heat insulating material 83 is the same as the heat insulating material 73. Further, the heat insulating material 83 is formed with a slit in a portion of the matting side of the mat in the thickness direction. The slit is shaped to form a non-cooling path 82a. Hot material The lower end of the lower end of the horizontal portion 53a extends to the vicinity of the rear side of the horizontal portion 53a (see Fig. 14). The size of the slit in the left-right direction is arbitrary, but it is preferably a range in which the entire lateral direction of the plurality of mist discharge pins 57 is accommodated. The first mist cold air supply port 62 and the second mist cold air supply port 84 (see FIGS. 13 to 15) are the same as the mist cold air supply port of the first embodiment. The second mist cold air supply port 84 is used. The wind introduced into the non-cooling path 82a in the wind generated by the refrigerating blower fan 35 is introduced into the opening in 45 (the flow of the wind is as indicated by arrows di, D2, and D3 in Fig. 14). The cold air supply port 84 is provided at a position facing the mist discharge pin 57 of the mist discharge unit 50 in the front wall portion 36a. Further, the mist generation chamber 45 has a plurality of winds introduced from the second mist cold air supply port 84 to the plurality of The guide member 85 of the mist release pin 57. The guide member 85 of the third embodiment is provided on the back side (back side) of the horizontal portion 53a of the mist generating unit 51, and is a triangular prism that extends in parallel along the horizontal portion 53a. When from the side of the refrigerator body 1 When the guide member 85 is observed, one of the apex angles of the triangular shape of the guide member 85 extends to the vicinity of the center in the vertical direction of the second cold air supply port 84. 32 201202644 According to the configuration of the third embodiment, by refrigeration The wind that has passed through the non-cooling path 82a in the wind generated by the air blowing action of the blower fan 35 is cooled by the cooler 24 and is introduced into the mist generating chamber 45 from the second mist cold air supply port 84. The wind introduced by the cold air supply port 84 is blown to the guide member 85 to be vertically separated. The wind that has flowed upward after separation (see an arrow D2 shown in Figs. 13 and 14) is easily blown onto the horizontal portion 53a of the mist release pin 57. The mist discharge pin 57 is supplied from each of the mist blowing outlets 64, 65, 66 located in the vicinity of the mist discharge pin 57 to each storage compartment (especially (refrigerator compartment 3, microfreezer compartment 14, egg box 15) β mist blowing outlet 67 In particular, it is supplied to the vegetable compartment 4.

Each storage room. Further, the wind that has flowed downward after separation (see an arrow D3 shown in FIG. 13 and FIG. 14) is easily blown to the mist discharge pin 57 provided under the horizontal portion 53a of the mist release pin 57, and is located at the mist discharge pin 57. The vegetable compartment in the vicinity is 85, so that the simple structure of only the mouth 84 can be used to obtain the first effect of improving the productivity of the refrigerator. By providing the mist generating chamber 45 with the bow guide member, the second mist air supply is provided at one place. The same effect of the port 2 embodiment. The rate. Except for this, the third embodiment has the same effect as that of the second embodiment.

As described above, the refrigerator according to the present embodiment employs a configuration in which a mist chamber that generates mist from a mist generating mechanism is provided in the refrigerator body, and the mist generating chamber has a supply of wind generated by the air blowing mechanism. The mouth and the mist outlet that communicates with the storage room. In this, the mist generated by the mist generating mechanism is convected in the mist generating chamber by the wind introduced from the air supply port, and is supplied from the mist blowing port to the living room.

Therefore, the mist generated by the mist generating device can be supplied to the storage chamber at a uniform concentration. A (Fourth Embodiment) Fig. 16 shows a fourth embodiment. In the fourth embodiment, the configuration of the mist generating unit 76 is different from that of the first embodiment in the electrostatic atomizing device 75 constituting the mist generating device. The mist generating unit 76 includes a mist releasing portion 77 and a water supply portion 78 that supplies water to the mist releasing portion π. The water supply unit 78 has a circular portion 78a that is circular in a front view and a vertical portion 78b that extends downward from the circular portion 78a, and houses the water retaining material 55 similar to that of the first embodiment in the case 79. The lower end portion of the vertical portion 78b penetrates the lower portion of the duct constituent member 46 and the front portion 36b (see FIG. 8) of the refrigerating cooler chamber 36, and is inserted into the water storage container 56 provided in the refrigerating cooler chamber 36 from above. Inside. The circular portion 78a and the vertical portion 78b of the water supply portion 78 are disposed along the front wall 36a so as to be parallel to the front wall 36a of the refrigerating cooler chamber 36 in the cold air duct 34. 34 201202644 The mist releasing portion 77 is composed of a plurality of mist releasing pins 57 constituting the projections. The mist release pin 57 is radially provided on the outer peripheral portion of the circular portion. Therefore, the mist releasing portion 77 is constituted by a plurality of mist projections 57 (projecting portions) that protrude in the non-direction. The bottom end portion of each of the mist discharge pins 57 passes through the case 79 to contact the water retaining material 55. Each of the mist discharge pins 57 is also disposed along the front wall so as to be parallel to the front wall 36a of the refrigerator compartment 36 in the cold air duct 。. A protruding portion 78C projecting to the left side is provided in the left portion of the circular portion 78a of the water supply portion 78, and a power receiving pin 58 is provided on the protruding portion 78e so as to protrude leftward. The power receiving pin 58 is connected to the & electrical terminal 61 on the power supply unit 52 side. In this configuration, the water stored in the water storage container 56 is sucked by the water retaining material 55 and supplied to the respective mist discharge pins 57. Further, 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 55, 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 mist release pin 57 (the mist outlet 64 for the refrigerator compartment, the mist outlet 65 for the micro-freezer, the mist outlet 66 for the egg box, and the vegetable compartment. The mist blowing outlets 67) are supplied to a plurality of supply destinations such as the refrigerator compartment 3, the micro-freezing compartment 14, the egg cartridge 15, and the vegetable compartment 4. In the mist generating device of the present embodiment, in particular, the mist releasing pin 57 is radially arranged. Therefore, compared with the case of the first embodiment, there is an advantage that the mist can be discharged in more directions. 〃 35 201202644 In addition, in the embodiment of Fig. 16, as in the second embodiment, Fig. 12, a supply air blower 74 to the mist generating chamber 45 may be provided. Supply = β is used to supply the air through the non-cooling path 72a to the opening in the mist generating chamber 45 by the air blowing action of the refrigerating air blowing fan 35, and the following configuration is adopted, that is, by providing such a air supply port Therefore, the mist is released by cooling the H-front ridge gas, and the released mist is supplied to the storage room. The gz money (four) is stopped in the nacelle or the surface is released. As described above, the refrigerator according to the present embodiment The invention includes a refrigerator body having a storage compartment, a mist generating mechanism of the production line, and a mist generating chamber provided in the refrigerator body and accommodating the mist generating mechanism. In the mist generating chamber, a plurality of mist blowing outlets for differently supplying the mist generated by the mist generating means are provided. The mist discharge portion, the water supply portion that supplies water to the mist discharge portion, and the power supply device that applies a negative voltage to the mist discharge portion, the mist discharge portion is composed of a plurality of projections that protrude in different directions. With this configuration, the supply direction of the mist generated in the mist generating chamber can be set in a plurality of directions, and the supply target can be supplied to a plurality of supply targets, and the supply range of the mist can be widened to expand the effect range of the mist. (Fifth Embodiment) Figs. 17 to 20 show a fifth embodiment. In the fifth embodiment, unlike the fourth embodiment, a configuration is adopted in which a mist-inducing mechanism such as a beverage is prevented from being formed, and the performance of the mist generating device is lowered. As shown in FIGS. 16 to 2B, the mist generating chamber 45 is formed by a front wall 36a as a rear wall and a duct constituent member 46 as a covering portion, and the front wall 36 201202644 36a is located at the rear of the micro-freezing chamber 14 and The surface of the refrigerating cooler is mounted on the front wall; the first side engaging portion 46a (the upper side of the card) and the lower portion 46b are mounted on the front wall; (Bottom-engagement portion) ^ The wall 36a is detachably attached (see Fig. 2A) β. At this time, the lower portion of the lower side engaging portion 46b of the catheter constituting member 46 is disposed above the fourth portion of the catheter constituting member 46, and the partition wall 丨〇 is disposed at the lower engaging portion 46 of the catheter constituting member 46: The mist generating chamber 45 has a small depth dimension along the front wall 3 as in the left-right direction, and forms a (9) flat posture. And the inside of the mist generating chamber 45, that is, the main body portion of the inside of the duct constituting member (9) which is used for generating the mist of the mist generating device, is used to form a chamber. That is, the duct is formed above the lid. And formed. As shown in FIG. 18 to FIG. 20, in the mist generating chamber 45, that is, above the lower portion of the front wall 36a, the front portion of the front wall 36a is further protruded forward from the inclined portion. 180. The upper surface of the human wfrn-circuit is provided with a circuit board m having a light source, and an arch-like cover 182. Specifically, the urging 36h is located above the upper engaging portion 37 201202644 46a of the duct constituting member 46, and is provided integrally with the front wall 36a so as to protrude forward from the inclined portion 36d. A hole (not shown) for locking the locking claw 182a (see Figs. 19 and 2B) provided on the cover 182 is provided in a part of the front end of the weir 36h. On the upper surface of the crucible 36h, a circuit board 181 on which two light-emitting diodes 181b and 181c serving as light sources are mounted is disposed obliquely upward toward the front, that is, toward the mounting table 47. At this time, as shown in Fig. 17, one of the two light-emitting diodes 181b, 181c is disposed closer to the vicinity of the center of the micro-frozen box 18. Further, another light emitting diode 181c is provided near the center of the egg box 15 and the small box 16. A water stopping portion 36e that protrudes upward from the inclined portion 36d is provided integrally with the front wall 36a at the rear of the circuit board 181. The groove portion 36f is formed by the water stopping portion 3 and the inclined portion 36d. # The groove portion 36f is a width in the left-right direction of the illumination unit 18A and is set again. Further, the water stopping portion 36e is further protruded forward and is provided with a locking portion 36g. At this time, the water stop portion 36e protrudes higher than the locking portion 3. A hole (not shown) for locking the locking claw 182b which is not provided on the cover 182 is also provided in a part of the front end of the locking portion 36g. For example, the locking claws provided at the both end edges of the front-rear direction are locked, and the locking holes are provided in the locking holes provided in the 36h and the locking portions 36g. Therefore, on the inner side surface of the cover 182, fine grooves are formed by knuding processing or engraving processing, whereby light from the light-emitting diodes 181b and 181c is diffused and irradiated. 38 201202644 As shown in Figs. 17 to 20, a mounting table 47 is provided above the mist generating chamber 45. The mounting table 47 forms a top surface 'of the freezing chamber 14 below the refrigerating compartment 3 and mounts a stored object or the like on the upper surface. The mounting table 47 is supported by the support portion 49 provided at the rear portion of the refrigerating chamber 3 (micro-freezing chamber 14) and the holding portion 41 provided on the left and right side walls (see Fig. 17, only one side is shown). On the support portion 49, a fitting convex portion 49a facing upward is provided integrally with the branch portion 49. Further, on the lower surface of the rear portion of the mounting table 47, a merging recess 47a fitted to the fitting convex portion 49a is provided. By fitting the fitting recessed portion 47a to the fitting convex portion 49a, the placing table 47 and the supporting portion 49 are positioned and fixed so that the placing table 47 does not fall forward. In this case, the fitting convex portion 49a may be provided in a wide range in the left-right direction, for example, or a cylindrical or quadrangular prism-shaped convex portion may be provided at least in one place. In the mounting table 47, the left and right peripheral portions are raised to surround the three sides other than the front portion, and the drip prevention portion 47b constituting the drip prevention mechanism is provided. Thereby, even when a drink or a food juice or the like is sprinkled on the upper surface of the mounting table 47, the beverage or the food juice can be prevented from dropping to the lower side of the mounting table 47 to some extent. In this case, the drip-proof portion 47b of the drip-proof mechanism may be provided with a recessed portion on the left and right and rear peripheral portions of the mounting table 47 to store a spilled beverage, food juice, etc., or a sponge having a water absorption property (Sp〇nge) or the like. The structure that comes to absorb water. Further, the mounting table 47 has a reflecting surface 47c which is formed with a wrinkle processing in which the shape of the fine portion 39 201202644 is formed on the entire lower surface as a reflecting means for the light irradiated from the illumination unit 180. Therefore, a large portion of the light irradiated from the illumination unit 18A toward the mounting table 47 can be reflected into the lower egg cassette 15 and the micro-frozen box 18. Thereby, the inside of each of the cartridges can be efficiently illuminated to improve the visibility in the cartridges. Further, the light that is not reflected by the reflecting surface 47c and transmitted through the mounting table 47 is diffused by the pleating process. As a result, the light that is irradiated obliquely upward from the illumination unit 8A does not "directly reach the user's gaze through the mounting table 47", so that the glare to the user can be reduced. Further, the reflecting surface 47c of the mounting table 47 may be configured to perform entanglement processing only on a portion that irradiates light from the illumination unit 180. Further, the reflecting surface 47c may have a structure in which a back surface (or a surface) of the mounting table 47 is subjected to a hot stamp such as silver gloss, or a film in which aluminum is vapor-deposited. . Thereby, the reflectance of the mounting table 47 is improved, and the inside of each of the cassettes (egg box 15 and the micro-frozen box 18) can be illuminated more brightly. Next, the micro-bed cassette 18 in the micro-freezing compartment 14 disposed in front of the illumination unit 180 will be described in detail. The east case 18 is a box-shaped storage container whose upper surface is open and whose rear portion is set lower than the front portion. In the micro-frozen box 18, a notch portion i8d (see Figs. 1 and 19) is provided below the illumination unit 180. Specifically, the wall constituting the periphery of the micro-frozen box 18 is set such that the rear plate 18a is lower than the front plate 18b and located below the illumination unit 18A (refer to Fig. 201202644)

L 19, Figure 20). Further, the front plate 18b and the rear plate 18a are sandwiched by the left and right side plates 18c having the slits at the rear upper portion, thereby forming a notch portion 18d in which the peripheral wall is cut at the rear portion of the microfrozen box 18. Thereby, the illumination unit 180 can be irradiated without being blocked by the rear plate 18a and the side plate 18c constituting the micro-frozen box 18, and the internal volume of the micro-frozen box 18 can be largely ensured. As shown in FIG. 20, the cold air supply port anvil for supplying the cold air from the refrigerating cooler 24 to the micro-freezing chamber 14 and the micro-freezing box 18 is above the cutout portion 18d of the bead box 18 and is illuminated. The lower portion ' of the unit 18' is located in front of the lighting unit 18A. Further, a heat insulating material 38 is provided between the refrigerating cooler 24 housed behind the duct constituent member 46 and the illumination unit 180. Thereby, it is possible to prevent the cold air from the refrigerating cooler 24 from directly contacting the circuit board 181' of the illumination unit, especially the back surface of the light-emitting diode 丨 which generates a large amount of heat. Therefore, it is possible to prevent condensation from being generated by the cold air contacting the circuit board m. According to the fifth embodiment, the following effects can be obtained. According to the configuration of the present embodiment, the static electricity generated by the mist is used as the main body portion. It is housed in the mist generating portion 45, and is placed inside the member 46, and is formed by the conduit member 46 above the device 48. (4) ^ The cover is electrostatically atomized 201202644

L and 'will cause the refrigerating compartment of the storage compartment C refrigerating compartment 3, the vegetable compartment 4, the micro-freezing compartment 14, the egg cartridge 15, and the storage compartment 16 by the electrostatic flying device 48 to be blown out by the mist blowing outlet 64 and the mist. The outlet 65, the egg box mist blowing outlet 66, and the vegetable compartment bundle are different from the front surface or the lower surface or the rear surface of the catheter forming member 46 which is provided in the mist generating chamber 45, in particular, directly The blowout outlet 65 that connects the mist generating chamber 45 and the refrigerating compartment 3, the egglet mist outlet 66, and the vegetable compartment mist outlet π may not be provided in the mist generating chamber 45, that is, the guide f constituent member 46 is based on the structure 'in the mist The upper surface of the chamber 45 is created to create a mist discharge port in the chamber 45. The mist is connected to the mist. Therefore, it is possible to prevent the liquid such as the beverage or the food juice from entering the mist generating chamber 45 from the mist. # Therefore, it is possible to prevent the performance of the electrostatic atomizing device 48 generated by the electrostatic atomizing device 48 accommodated in the mist generating chamber 45 in the storage chamber, particularly the mist releasing pin 57, from being deteriorated or moldy. The production of strange smell. The mounting block 47 is provided above the mist generating chamber 45 in a form supported by the support portion 49. According to this configuration, the storage property in the refrigerating compartment 3 is increased by placing the stored matter on the upper surface of the mounting surface 47. Further, when a liquid such as a drink or a food juice is scattered on the surface of the mounting table 47, the liquid easily drips along the gap between the mounting table 47 and the support portion 49. However, in the present embodiment, the refrigerator is used. The rear portion of the 3 (micro-freezing chamber 14) is provided with a support portion 49 and a mist chamber 42 201202644 living room 45 having an upper surface without a mist outlet. ^ ^In the case where the liquid follows the mounting table ==, since the mist generating chamber is not provided with a port, it is possible to prevent liquid from entering the mist generating chamber #. Furthermore, in the case of the A 47 !_ h type, the squares of the two sides except the front part are provided: 峨t=n==r7b. According to this, even in the case of the upper surface of ^t σ 47, it is possible to prevent the liquid from dripping below the mounting table 47 with a certain degree of privacy. They 23, 46 are engaged in the front part of the refrigerating device chamber 36. Further, a weir 36h is provided above the upper engaging portion 46a of the duct constituent member 46. According to this configuration, it is possible to prevent the liquid from being detached from the mounting portion by means of the 36h. Thereby, it is possible to prevent the liquid on the mounting port 47 from entering the chamber illusion from the upper engaging portion as much as possible. In addition, the micro-freezing chamber is provided with a mist blowing outlet 65 and an egg cartridge with a mist blowing outlet projecting upward from the upper portion of the duct constituent member 46. According to this configuration, it is possible to more effectively prevent the liquid from entering the mist generating chamber 45 by the mist blowing outlet 65° from the micro-freezing chamber and the egg cartridge blowing outlet 66. Further, the partition wall 10 is disposed above the lower engaging portion 46b of the duct constituent member 46. Further, a convex portion 10a protruding in a convex shape is provided on the rear edge portion of the partition wall 1B, and the convex portion 1a is located above the lower portion 46b. According to this, the liquid that is dropped from the mounting table 47 to the upper surface of the partition wall 1〇w 2012 201244 44 Λ liquid does not travel further to the convex portion 1〇3, and the lower side engaging portion 46b of the duct constituent member 46 2. The liquid is introduced into the mist chamber 45 from the gap of the lower engaging portion 46b, and includes the electrostatic atomizing device 48 of the present embodiment and is generally a high-powered component or a fragile precision. In the case of the whole part, Benzhong 1';* is not good in the operation of exposing such a device and performing maintenance such as cleaning by the user. Here, in the present embodiment, when the upper surface of the fine payment placing table 47 is used, it is difficult to enter the mist generating chamber 45 in which the electrostatic atomizing device 48 is housed, so that the liquid is reduced. The possibility of the Yu (4) device 48 is low. * Therefore, the user does not need to expose the electrostatic atomizing device 48 to perform cleaning, and is therefore excellent in wiping the liquid adhering to the front surface of the catheter constituting member 46 or the upper surface of the partition wall 10 which is normally exposed. . (Sixth embodiment) Fig. 21 shows a sixth embodiment. The third embodiment differs from the fifth embodiment in the configuration of the vegetable chamber mist blowing port 183 which supplies the vegetable compartment 4 with mist. In the same manner as the fifth embodiment, the refrigerator compartment 3 and the vegetable compartment 4 are vertically partitioned from the partition wall 184 of the floor of the refrigerator compartment 3, and are vertically spaced apart from the rear edge of the partition wall 184, and have a convex shape convex upward. The portion 18 is, for example, and is provided with a communication port 185 that communicates with the vegetable compartment 4. The mist generated in the mist generating chamber 45 is supplied to the vegetable compartment of the vegetable compartment 4 201202644 The mist blowing outlet 183 is formed above the communication port 185 and has a weir and a lower opening.詹 ° This is a configuration in which the lower portion of the right side of the duct constituting member 46 # seen from the front view of the mist generating chamber 45 extends to the front side of the convex portion 184a of the partition wall 184. Thereby, the vegetable compartment mist outlet 183 communicates with the vegetable compartment 4 via the communication port 185. Also, the communication port 185 is covered by the 檐183a. According to the configuration of the sixth embodiment, the vegetable chamber mist outlet 183 has the crucible 183a extending obliquely downward in the forward direction. Therefore, even if the liquid such as the beverage or the food juice follows the duct constituent member 46 and reaches the vegetable chamber mist outlet 183, It is possible to prevent the liquid from entering the mist generating chamber 45 from the vegetable compartment by the mist blowing outlet 183. Further, the crucible 183a is provided so as to extend to the front side of the convex portion 184a of the partition wall 184. Therefore, even when the liquid drips to the partition wall 184 along the crucible 183a, the convex portion 184a can be prevented by the convex portion 184a. The liquid enters the communication port 185. That is, it is possible to prevent the liquid from entering the vegetable compartment 4 from the communication port 185. Therefore, the user only needs to wipe the partition wall 184, and the workability is further improved. As described above, in the refrigerator according to the present embodiment, the mist generating chamber accommodates the mist generating mechanism that generates the mist and covers the upper portion of the mist generating mechanism, and a mist blowing port is provided at a position different from the upper surface of the mist generating chamber. Therefore, even when there is a drink or a food juice or the like spilled into the storage chamber, especially above the mist generating chamber, it is possible to prevent the spilled beverage or food from entering the mist generating chamber, thereby preventing these beverages or foods. The juice flows into and attaches to the mist generating mechanism. The embodiments of the present invention have been described, but are not intended to limit the scope of the invention. The present invention can be implemented in various other forms, and various omissions, substitutions, and changes can be made without departing from the spirit of the invention. The invention or its modifications are intended to be included within the scope of the invention and the scope of the invention. For example, the number and position of the cold air supply ports for the mist, the number and position of the mist blowing ports, and the shape of the mist discharge pin can be appropriately changed without departing from the scope of the above. While the present invention has been described in its preferred embodiments, the present invention is not intended to limit the invention, and the present invention may be modified and modified without departing from the spirit and scope of the invention. The scope of protection is subject to the definition of the scope of the patent application. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a vertical cross-sectional side view showing a schematic configuration of an entire refrigerator in a first embodiment. Fig. 2 is a front elevational view showing the refrigerator main body in a state in which a door or a shelf is removed. Fig. 3 is a schematic perspective view of the vicinity of a micro-freezing chamber. Figure 4 is an enlarged front elevational view of the periphery of the mist generating chamber. Figure 5 is a cross-sectional plan view taken along the line X1-X1 in Figure 4 . Fig. 6 is a longitudinal sectional side view taken along line X2-X2 of Fig. 4; 46 201202644 A longitudinal sectional side view of the X3〇C3 line in Fig. 4. Next, a longitudinal sectional side view of the X4_X4 line in Fig. 4 is shown.圄 is a longitudinal sectional view of the part of the electrostatic atomization device. The diagram corresponding to FIG. 4 of the second embodiment is not shown. Fig. 11 is a view corresponding to Fig. 6. Fig. 12 is a view corresponding to Fig. 9; The figure corresponding to FIG. 4 of the third embodiment is not shown. Fig. 14 is a view corresponding to Fig. 6; Fig. 15 is a view corresponding to Fig. 9; FIG. 16 is a view corresponding to FIG. 9 showing the mist generating device of the fourth embodiment. (4) is a longitudinal cross-sectional side view showing the enlarged front side of the vicinity of the mist generating chamber of the fifth embodiment, taken along the line X2-X2 in Fig. 17 . , do not look at the longitudinal section of the (four) Χ 3 line. =, a longitudinal sectional side view of the line (10) in Fig. 17. Longitudinal section front view of the portion of the electrostatically atomizing device in the vicinity of the mist generating chamber of the sixth embodiment of the present invention. [Main component symbol description] 1 : Refrigerator body 2: Heat insulating box 2a: Outer box 2b: Inside Box (1st path member) 2c. Insulation material 201202644 -----Γ.^ 3 : Refrigeration room (storage room) 3a, 4a, 5a, 7a: Heat insulation door 4: Vegetable room (storage room) 5: System Ice chamber 6: Small freezer compartment 7: Freezer compartment 8: Automatic ice making device 8a: Ice making box 10, 184: Partition wall 10a, 184a: Projection 11: Lower box 12: Upper box 13: Shelf 14: Micro-frozen Room 15: Egg box 16: Small box 17: Water tank 18: Micro-frozen box 18a: Rear plate 18b: Front plate 18c: Left and right side plates 18d: Notched portion 19: Thermal insulation partition wall 20: Ice storage container 48 201202644 22: Storage Container 24: refrigerating cooler 25: refrigerating cooler 26: machine room 27: compressor 28: defrosting water evaporating dish 29: control device 30: freezing cooler chamber 30a: cold air blowing port 30b: return port 31: Cooling air supply fan 32, 40: Drain pipe 34: Cold air duct 35: Refrigeration air supply fan 36: Refrigerator cooler chamber 36a: Front wall (2nd road) Member 36b: Segment 36c: Lower projection 36d: Inclined portion 36e: Water stop portion 36f: Groove portion 36g: Engagement portion 36h, 183a: 檐37: Cold air supply conduit 49 201202644 A. 38: Thermal insulation material (No. 1 path member) 39: cold air supply port 41: holding portion 42: air supply duct 43: suction port 44, 185: communication port 45: mist generating chamber 46: duct constituent member 46a: upper side engaging portion 46b: lower side engaging portion 47: mounting table 47a: fitting recess 47b: drip-proof portion 47c: reflecting surfaces 48, 75: electrostatic atomizing device (fog generating mechanism) 49: supporting portion 49a: fitting convex portions 50, 77: mist releasing portion 51, 76: mist generating unit (fog generating mechanism) 52: power supply device 53, 78: water supply portion 53a: horizontal portion 53b, 78b: vertical portion 53c: curved portion 50 201202644 54, 79: case 55: water retaining material 56: water storage container 56a: overflowing section 57 · mist discharge pin (projection) 58 : power receiving pin 60 : wire 61 : power supply terminal 62 : cold air supply port for mist (first air supply port for mist) 63 : duct for mist facing the refrigerator compartment 64: Fog outlet 65 for refrigerating compartment: Mist outlet 66 for micro-freezer: Mist outlet 67, 183 for egg box: The mist blowing outlet 68 for the vegetable compartment: the air supply duct 70 for the micro-freezing compartment: the defrosting heater 71: the first path member 71a: the cooling path 72: the second path member 72a, 82a: the non-cooling path 73: the heat insulating material ( Second path member) 74: air supply port 74a: upper air supply port 74b: lower side air supply port 51 201202644

a L 78a : circular portion 78c : protruding portion 82 : second path member 83 : heat insulating member (second path member) 84 : second mist cold air supply port 85 : guiding member 180 : lighting unit 181 : circuit board 181b 181c: light-emitting diode 182: cover 182a, 182b: locking claw Α 1 Ά 2 ' Bl ' B2 ' B3 ' Cl ' C2 ' C3 > Dl ' D2 ' D3 : arrow 52

Claims (1)

201202644 VII. Patent application scope: 1. A refrigerator, comprising: a refrigerator body having a plurality of storage compartments; and a cooler disposed in the refrigerator body to generate cold air that is inclined to cool the storage room; a mechanism, disposed in the refrigerator body and generating wind; a mist generating mechanism having a water storage portion to atomize water of the water storage portion to generate fog; and a mist generating chamber disposed in the refrigerator body In the mist generating unit, the mist generating chamber has a supply port for introducing the wind generated by the air blowing means, and a plurality of mist blowing ports for supplying the plurality of storage chambers, and the mist generating means generates the mist generating means. The mist is blown from the plurality of mists and supplied to the plurality of storage chambers so that the supply target of the mist is different. 2. The refrigerator according to claim 1, wherein the refrigerator has a cartridge in a storage chamber of the supply target of the mist blown from the mist outlet. 3. The refrigerator according to claim 1, wherein the mist generating mechanism has a plurality of enemy pins protruding in different directions. 4. The refrigerator according to claim 3, wherein the plurality of mist discharge pins are arranged in two upper and lower sections. 5. The refrigerator according to claim 1, wherein: in the refrigerator body, a cold air duct for supplying cold air to the storage compartment is provided, the mist generating chamber being along the cold air duct Further, the cold air duct is provided with a cold air supply port for mist which is a supply port for supplying cold air to the mist generating chamber. 6. The refrigerator according to claim 1, wherein the mist generating mechanism has a mist releasing pin for generating mist, and the plurality of mist blowing ports of the mist generating chamber are disposed opposite to the mist Release the pin at a different location. 7. The refrigerator according to claim 1, wherein the mist generating chamber covers an upper portion of the mist generating mechanism, and the mist is provided at a position different from an upper surface of the mist generating chamber. The mist generated by the generating mechanism is supplied to the mist blowing outlet of the storage compartment. 8. The refrigerator according to claim 7, wherein a mounting table on which the stored matter is placed is provided above the mist generating chamber. 9. The refrigerator according to claim 7, wherein a support portion for supporting the mounting table and the mist generating chamber are provided at a rear portion of the storage compartment. 10. The refrigerator according to claim 7, wherein a drip-proof mechanism is provided at a rear edge portion of the mounting table. 11. The refrigerator according to claim 7, wherein the mist generating chamber is engaged with a rear wall provided in the storage compartment to mount an engaging portion of the upper side of the mist generating chamber. There are articles on the top. The refrigerator according to claim 7, wherein the mist is provided in a front portion of the mist generating chamber so as to protrude forward. The refrigerator according to claim 7, wherein a bottom plate of the storage compartment is disposed above an engagement portion on a lower side of the mist generating chamber. The refrigerator according to claim 7, wherein the rear edge portion of the bottom plate has a convex portion having a convex shape that protrudes upward, and the convex portion is located at a lower side of the mist generating chamber. Above the joint. 15. The refrigerator according to claim 1, wherein a part of the air that has passed through the cooler and is circulated by the blower is supplied to the mist discharge pin, and the mist is to be The mist discharged from the discharge pin is supplied to the storage chamber together with the air. 16. The refrigerator according to claim 15, wherein the cooler is disposed in a conduit that is traversed by the blower, the mist discharge pin is disposed outside the conduit & Above, the air supply port that cools the passage to the mist generating chamber is provided. The refrigerator according to claim 16, wherein the duct has an i-th protruding portion in which the cooler is disposed, and a second portion of the first protrusion iUp and a water portion in which the water portion is disposed The air supply port is disposed on the first protrusion. 55