TW201205019A - Refrigerator - Google Patents

Abstract

A refrigerator includes a pipe for accepting the defrosting water of a cooler, and a water storage portion for storing the water applied with a voltage. In the refrigerator, a connection between the water dropping from the storage portion and the defrosting water at the pipe side is prevented, such that a voltage is prevented from being applied to the cooler. The refrigerator includes a cooler; a storage portion, for storing the water applied with a voltage; and a pipe, installed to be in contact with the cooler and to accept the defrosting water generated during defrosting of the cooler. A partition portion is installed in the pipe for performing partition, so that a connection between the water dropping from the storage portion and the defrosting water coming from the cooler will not occur.

Description

201205019 VI. Description of the Invention: TECHNICAL FIELD OF THE INVENTION Embodiments of the present invention relate to a refrigerator. [Prior Art] In recent years, I have known a refrigerator having a mist generating device that is electrostatically atomized to produce a mist. The mist generates a projection for the skirt, and a structure for discharging (four) mist from the projection to the living chamber). The cold mist generator has a detachable water storage unit and is configured to atomize water in the water storage unit (for example, refer to the patent document 〇. Far away, in a domestic refrigerator, there is a type of cooling And a refrigerator that receives a drain pipe that flows out of the chilled water generated by the cooler (for example, refer to Patent Document 2). In such a refrigerator, for example, a storage device such as a mist generating device is present above the drain pipe. In the case of a water storage portion of a voltage-applied water, in particular, when water is continuously dropped from the water storage portion to the drain pipe, the dropped water is connected to the defrosted water flowing along the drain pipe, thereby possibly via This water applies a voltage to the cooler to cause the cooler to be charged. Therefore, 'when the defrosted water drops on the drain pipe, it is preferable to make the water drip continuously 'to avoid exceeding the drainage capacity of the drain pipe. Moreover, there is a drain pipe In the structure of the mechanism (water receiving part) that receives the water dropped from the water storage part, the water receiving part is required not to receive a large amount of water at a time to match the processing capacity such as drainage or discharge. [Patent Document] Japanese Patent Publication No. 2 (8) No. : The tube of water and the refrigerator in the water storage part of the water to which the voltage is applied, the second is enough to prevent the money from the water storage part (four) age frost water = prevent the voltage from being applied to the cooling II. Moreover, the present invention provides a refrigerator, The water is dripped from the water storage portion to the drain pipe (water receiving portion). The refrigerator of the present embodiment is characterized by comprising: a cooler; storing and storing the applied voltage water for the atomizing device And the tube is provided in a manner of being in contact with the cooler, and receives the defrosting water generated by the defrosting of the cold (four) and is provided with a partition in the tube that receives the defrosting water, The partition is partitioned to prevent the water dripping from the water storage portion from being connected to the defrosted water from the cooler. Further, the refrigerator of the present embodiment is characterized in that the water storage unit is provided with Discharge the stored water to the drain, and A water passage continuous from the surface of the drain portion to the back surface is provided, and water stored in the water storage portion is configured to continuously drip into the tube through the water passage by capillary action. The above and other objects, features, and advantages of the present invention will become more apparent and understood. In the following, a refrigerator (refrigerator) of a plurality of embodiments will be described with reference to the drawings. In the respective embodiments, substantially the same components are denoted by the same reference numerals, and description thereof will be omitted. (First embodiment) First The first embodiment will be described with reference to Fig. 1 to Fig. 18 (a) and Fig. 18 (b). As shown in Fig. 1 and Fig. 2, the refrigerator body 丨 is a vertically long rectangular box-shaped heat insulation box that is open on the front surface. In the body 2, a plurality of storage chambers are arranged in the vertical direction. Specifically, in the heat insulating box 2, the refrigerating chamber 3 and the vegetable compartment 4 are sequentially provided from the upper stage, and the ice making compartment 5 and the small freezing compartment 6' are disposed below the left and right sides thereof. There is a freezer compartment 7. Inside the ice making chamber 5, a well-known automatic ice making device 8 is provided (refer to Fig. 1). Further, the heat insulating box 2 is basically constructed by providing a heat insulating material between the outer casing 2a made of a steel plate and the inner box 2b made of synthetic resin. The refrigerating compartment 3 and the vegetable compartment 4 are storage compartments of a refrigerating temperature section, and the compartments 1 and the vegetable compartments 4 are partitioned by a partition wall 1 made of plastic. Usually, the maintenance temperature of the refrigerating compartment 3 is set to iO to yC, and the maintenance temperature of the vegetable compartment 4 is set to be slightly higher than rc~6〇c. In the front surface portion of the refrigerating compartment 3, a hinge opening and closing type heat insulating door 3a' is provided on the front surface of the vegetable compartment 4, and a suction type heat insulating door 4& The lower case u constituting the storage container is connected to the back surface of the heat insulating door 4a. In the upper portion of the lower casing 11, an upper casing 12 which is smaller than the lower casing u is provided. The inside of the refrigerating compartment 3 is vertically divided into a plurality of sections by a plurality of shelves 13. As shown in Fig. 201205019 3, 'the lowermost part in the refrigerating compartment 3 (the upper part of the partition wall i〇), the chilled chamber 14 is provided on the right side, and the egg box 15 and the small box 16 are provided on the left side of the left side. 'Further, there is a water tank Π on their left side. The water storage tank 17 is for storing water supplied to the ice making box 8a of the automatic ice making device 8 and is detachably mountable by a user. A micro-freezing box 18 is provided in the micro-compartment 14 in an accessible manner. A mounting plate 7 is provided from an upper portion of the micro-freezing chamber 14 to an upper portion of a portion where the water storage tank 17 is provided. As shown in Fig. 9, a partitioning plate 71a is provided between the micro-freezing chamber 14 and the egg box].5 and the setting portion of the small-sized box 16, and the setting portion and the water tank opening of the egg box 15 and the small-sized box 16 are provided. A partition plate 71b is also provided between the installation portions. The placing plate 70 constitutes a top plate portion of the micro-freezing chamber 14, and the upper portion of the micro-freezing chamber 14 is closed by the placing plate 70. The front surface of the micro-freezing chamber 14 is closed by the front surface wall iga of the micro-ticket case 18 in the storage state. The maintenance temperature of the micro-freezing chamber 14 is slightly lower than that of the upper refrigerating compartment 3 and the lower compartment 4, and is set to, for example, 〇〇C to 1O. The micro-freezing chamber 14 and the lower cooking chamber 4 are vertically adjacent to each other via the partition wall 1〇. As shown in Fig. 1 and Fig. 10, in the rear upper portion of the micro-container box 18, the month is viewed from the front side from the upper left side wall of the financial box 18, the upper portion of the rear wall, and the front surface wall. The notch portion 18b is formed in a manner that the front side of the 18a and the left and right side walls is low. The ice making compartment 5, the small cold bundle chamber 6 and the cold bundle chamber 7 are both cold and warm, such as -18 C, and the vegetable compartment 4 and the ice making compartment 5 are separated from the chamber 6 by the heat insulating partition wall 19 Separate up and down. 1 8 201205019 A suction-type heat insulating door & is provided in the surface of the crucible to which the ice is placed to 5, and the ice storage container 2 is connected to the back surface of the heat insulating bucket 5a. 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. A suction-type heat insulating door 7a to which the storage container 22 is connected is also provided in the front surface portion of the cold-blowing chamber 7. ^ In the refrigerator main body 1, 'the refrigeration cycle (eycle) including the two coolers of the refrigerating cooler 24 and the refrigerating cooler 25 is incorporated, and the storage cooler 24 is used for the storage compartment of the refrigerating temperature section. That is, the refrigerating compartment 3 and the vegetable compartment 4 and the micro-freezing compartment 14 are cooled, and the refrigerating cooler is cooled by the cold shower; the jdl degree I is stored to the ice making chamber 5, the small cold; the east chamber 6 and the cold The chamber 7 is cooled. A machine room 26 is disposed on the back side of the lower end portion of the refrigerator body 1, and a compressor 27, a condenser, and the like constituting a refrigeration cycle are disposed in the machine room 26, and a cooling fan for cooling them is disposed. (fan) or defrosting water evaporates m 28 and the like. A control unit 29 to which a micro computer or the like for controlling the whole body is attached is provided at a lower portion of the rear surface of the refrigerator main body 1. The refrigeration cooler 24 and the cold cooler 25 are electrically connected indirectly to the outer casing 2a via a compressor 27 or the like which constitutes a refrigeration cycle together with these coolers 24 and 25. A freezing cooler chamber 30 is provided at the back of the freezing compartment 7 in the refrigerator main body 1. In the chiller chamber 3 of the chilling chamber, the lower portion is provided with the cold damper cooler 25 or a defrosting heater (not shown), and is disposed at the upper portion. There is a blowing fan 31 for freezing. In the cold 201205019, the intermediate portion 30a' of the front surface of the cold air chiller chamber 30 is provided with a return port 3〇b at the lower portion. a is cold; when the east fan fan 31, the cold air generated by the cold air 7 ρ is subjected to the following cycle: from the cold air outlet 30a to the ice making chamber 5, a small cold clothes After the ^^ n rr 』 is frozen to 6, in the freezer compartment 7, returning from the return 〇 30b to the cold; the east is used in the cooler chamber 3 。. By the cold air, the ice making chamber 5, the small cold chamber 6 and the cold beam chamber 7 are cooled. Further, in the blanking of the cold_cooler, a drain pipe 32 for defrosting water for defrosting the cold/east cooling H 25 is provided. The defrosted water received by the drain pipe 32 is led to the defrosted water provided in the machine room% outside the refrigerator to evaporate and evaporate. Further, in the refrigerator compartment 3 and the back of the vegetable compartment 4 in the refrigerator main body 1, a refrigerating cooler 24 or a cold air generated by the refrigerating cooler 24 is supplied to the refrigerating compartment. 3 (and vegetable compartment 4), a cold air duct 34, a refrigerating air blower fan 35 for circulating cold air, and the like. In other words, in the rear of the lowermost stage of the refrigerator compartment 3 in the refrigerator main body 1 (the rear side of the micro-freezing compartment 14), a refrigerating cooler chamber 36 constituting a part of the cold air duct 34 is provided in the refrigerating cooler chamber 36. A refrigerating cooler 24 is provided. The refrigerating cooler 24 is disposed in contact with a part of the inner box 2b (in this case, a portion where the refrigerating cooler chamber 36 is formed). In addition, at least the portion of the inner surface of the inner box 2b that is in contact with the refrigerating cooler 24 and the periphery of the portion (especially the lower portion) are attached with the main use 201205019 (seal). The defrosted water of the cooler 24 is a layer (not shown). ^ Above the refrigerating cooler chamber 36, a cold air duct 37 is extended upward. The upper end portion of the refrigerating chamber 11 is connected to the lower end portion of the cool air supply guide 37. At this time, the cold air duct 34 is constituted by the refrigerating cooler chamber 36 and the cold air supply duct 37. The front wall 36a of the refrigerating cooler chamber 36 protrudes further toward the cold air supply duct 37. Further, on the back side of the front wall 36a, a heat insulating material 38 having heat insulating properties is provided. In the front portion of the cool air supply duct 37, a plurality of cold air supply ports 39 opening into the refrigerating chamber 3 are provided. In a lower portion of the refrigerating cooler chamber 36, a drain pipe 40 (corresponding to a water receiving portion) is provided below the refrigerating cooler 24, and the drain pipe 4 receives the defrosting water from the refrigerating cooler 24 and Discharge to the outside of the refrigerator. As shown in FIG. 13, the drain pipe 40 is formed in a valley shape in which the bottom wall portion 40a, the rear wall portion 40b, the side wall portion 40c, the front wall portion 40d, and the protruding portion 4〇e are integrally formed, and the bottom wall is located therein. A drain port 41 is provided at a leftward position of the portion 4A, the left wall portion 40a is long in the left-right direction, and the rear wall portion 40b is erected at a rear portion of the bottom wall portion 4a, the side The wall portion 4〇c is erected on the left and right side portions of the bottom wall portion 40a, and the front wall portion 4〇d is provided at the front portion of the bottom wall portion 4〇a toward the obliquely upward direction, the protruding portion 4〇e The front right portion of the bottom wall portion 40a is provided so as to protrude forward. The bottom wall portion 40a is inclined downward toward the drain port 41. The left and right length dimensions of the drain pipe 40 and the depth dimension of the front and rear are set to be larger than the left and right length dimensions of the refrigerating cooler 24 and the depth dimension of the front and rear to form the 201205019 defrosting for all the drip from the refrigerating cooler 24 The size of the water. The defrosted water received by the drain pipe 40 is also discharged from the drain port 41 to the defrosted water provided in the machine room 26 outside the refrigerator, similarly to the defrosted water received by the drain pipe 32. The dish 28 was evaporated. Further, as shown in FIG. 12, the refrigerating cooler 24 has a coolant tube 24a arranged in a serpentine shape and a plurality of fins 24b, and the right end portion 24c of the coolant tube 24a is from the heat transfer fin 24b. Stand out to the side. On the front surface side of the rear wall portion 40b of the drain pipe 40, a support portion 4〇f that supports the coolant pipe 24a is integrally provided. The rear surface of the lower heat transfer fin 24b of the refrigerating cooler 24 is in contact with the front surface of the rear wall portion 4b of the drain pipe 4' (see Figs. 5 to 8 and 12). At this time, the rear surface of the lower heat transfer fin 24b in the refrigerating cooler 24 is in contact with the front surface of the rear wall portion 40b of the drain pipe 40, and also includes the defrosting generated when they are defrosted by the cooling cooling H24. Water contact. A rib-shaped partition portion 8G is integrally provided on the upper surface of the bottom wall portion 40a of the drain pipe 40. The partition portion 8G extends in the left-right direction along the rear wall portion 4Gb at the intermediate portion in the front-rear direction of the upper surface of the bottom (4) MQa, and the right end portion 80a is connected rearward to the left end of the rear wall portion at the rear of the protruding portion 4Qe. The portion 8〇b extends to the drain port 41 (the partition portion 80 is also inclined as shown in FIG. 14 as shown in FIG. 14 . The rear portion of the leek chamber 4 is disposed below the drain pipe 40). The air-sending fan 35' for refrigerating is provided with a blower duct 42 and a suction port 43. The air-supply duct 42 is connected to the refrigerating cooler chamber 36 (air-cooling duct 34) by means of the passage of the air duct_42. The opening 43 is opened in the vegetable compartment 4. The lower surface of the rear part of the partition wall 10 which constitutes the bottom of the refrigerating compartment 3 (the bottom of the micro-freezing compartment 14) is located in the vegetable to the side as shown in Fig. 1, Fig. 9, Fig. 1 A crisper cover 72 is attached to the upper portion of the fourth portion, and a ventilation path 73 extending in the left-right direction is formed between the fresh-keeping cover 72 and the partition wall 1A. As shown in Fig. 9, at the partition wall 10. The rear part is located behind the micro-freezing chamber 丨4 and is provided with a plurality of openings. The vent 74a is also provided with a vent 74b composed of a plurality of openings at the rear of the installation portion of the small box 16. These vents 74a, 74b allow the micro-freeze chamber 14 and the air passage 73 and the small box 16 to be The installation portion communicates with the air passage 73. The left and right side portions of the air passage 73 are open and the air passage 73 communicates with the upper portion of the vegetable compartment 4. Further, in the right corner portion of the rear portion of the partition wall 10, as shown in Fig. 5 A communication port 75 including a plurality of openings is formed behind the micro-freezing chamber 14. A V-duct 76 is provided below the communication port 75 as shown in Figs. 9 and 1B. The upper end portion of the 76 is communicated with the lower end portion of the microbead chamber 14' via the communication port 75 via the vent hole 77 (see FIG. 10) formed on the fresh-keeping cover 72 to communicate with the upper portion of the vegetable compartment 4. At this time, the micro-freezing chamber 14 The vent 74a and the communication port 75 function as an air outlet that serves as an outlet for the air in the micro-freezing chamber 14. Further, these vents 74a and the communication port 75 are disposed in the micro-frozen box 18; 201205019 = micro; bundle In the state of 14, it is not blocked by the box 18. The vent 74b in the installation portion of the storage unit 16 serves as a gas outlet for the phase of the small box 16, and is disposed at a position that is not blocked by the small box 16 in a state in which the small box 16 is accommodated. In this configuration, when the refrigerating blower fan 35 is driven, the inside of the vegetable compartment 4 (four) gas is sucked into the side of the trapping blower fan 35 from the suction population 43 as shown by the hollow arrow in Fig. 1, and the sucking air is blown out. The air supply duct is blown out to the air supply duct 42 to pass the air through the cold air duct 34 chamber and the cold air supply duct (7), and the cold air is taken out into the refrigerating chamber 3, and is also directly sent to the micro-freezing chamber 14 as will be described later. Inside. The air in the refrigerating room 3 and the financial room 14 (including the setting part of the small box 16-f^5) is mainly as shown in the arrow of Fig. 9 (1) jin = mouth 7 as, 7 servants flow out to the airway 73, and flows through the air passage 73 toward the left and right directions, and is supplied to the vegetable compartment 4 through the left and right outer surfaces of the upper casing 12 of the vegetable compartment 4. - ^ 'A part of the air in the micro-compartment 14 is as shown in the arrow C2 of (7). The following cycle 'that' is passed from the communication port 75 through the V-duct 76 and is supplied to the vegetable compartment 4 as it is supplied to the vegetable compartment. The air in 4 is finally sucked in by the refrigerating material fan 35. The air in the cooler chamber 36 for refrigerating is refrigerated and then becomes cold air. The cold air is supplied to the refrigerating chamber 3, the 201205019 micro-freezing chamber 14 and the vegetable compartment 4, thereby causing the refrigerating chamber 3, the micro-freezing chamber 14 and The vegetable compartment 4 is cooled to the temperature of the refrigerating temperature section. Further, as will be described later, a part of the cold air after passing through the refrigerating cooler 24 is directly supplied to the micro-freezing chamber 14, whereby the micro-freezing chamber 14 is maintained at a lower temperature than the refrigerating chamber 3 and the vegetable compartment 4. 〇~re). As shown in FIG. 2 and FIG. 4, the front side of the refrigerating cooler chamber 36 in the cold air duct 34 is provided with a special duct for mist, which is located on the right side and is located behind the micro-freezing chamber 14. 45. As shown in FIGS. 5 to 8, the special duct for mist 45 is formed by the front wall 36a of the refrigerating cooler chamber 36 and the duct constituent member 46 attached to the front surface of the refrigerating cooler chamber 36. The duct constituent member 46 that forms the special duct 45 for mist is detachably attached to the front wall 36a. At this time, the special duct 45 for mist is formed along the front wall 36a in a flat rectangular box shape which is long in the left-right direction and has a small depth in the front-rear direction. Further, in the special mist duct 45, the main body portion of the electrostatic atomizing device 48 is housed, and the electrostatic atomizing device 48 constitutes a mist generating device for generating mist. In addition to the mist generating mechanism, the electrostatic atomizing device 48 functions as a sterilizing component generating mechanism and a deodorizing component generating mechanism. Hereinafter, the electrostatic atomization device 48 will be described in detail. As shown in Fig. 11, the electrostatic atomizing device 48 includes a mist generating unit 51 having a mist releasing portion 5 and a power supply device (transformer) for applying a negative high voltage to the mist releasing portion 5〇. 15 201205019 53. The second generation: the second water supply portion of the water supply unit that supplies water to the mist discharge unit, the horizontal portion 53 & and the vertical portion 53b extending from the right end portion of the view to the 1" And from the front side = two: = element 51 is in the form of the box 54 provided: ==:=== = tube, the refrigeration cooler chamber 36 == 仃, arranged along the front wall 36a The water-repellent material 55 is, for example, a felt-like shape in which a fiber is wound, and is excellent in water and water retention, and the water storage container 56 (phase #水水部)_ (Defrost water). === (4) When the Xiangyang pipe draws water, the horizontal portion 53a of the water supply unit 53 is disposed in the special duct 45 for fog, and the lower end of the vertical portion 53b is as shown in Fig. 8. It is inserted into the refrigerating cooler chamber 36 through the hole formed in the lower portion of the pilot wheel and the front portion of the refrigerating cooler chamber 36. The outer portion of the lower portion of the inner layer of the water retaining material 55 is covered by the casing 54. In the water retaining material & the portion of the horizontal portion 53a and the portion of the vertical portion 53b may be composed of non-members. A front portion of the lower portion in the cooler chamber 36 is provided with a water storage container 56 (refer to Fig. 8) constituting a water storage portion. The water storage container 56 is located between the A cooler 24 and the drain pipe 4 存在 therebelow. Further, under the water 201205019, the front portion is attached to the lower 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 front of the water storage container 56 is attached. The lower portion 36c of the portion is located below the front wall 36a and protrudes (projects) forward from the front wall 36a via the segment portion 36b. If the front wall 36a is the first projection, the lower portion 36c will become The second protruding portion that protrudes further forward. The water storage container 56 is separated from the refrigerating cooler 24 and the inner box 2b and the drain pipe 40 forming the rear surface of the refrigerating cooler to 36 in a mounted state attached to the lower portion 36c. The detailed structure of the water storage container 56 will be described later. Between the water storage container 56 and the inner box 2b, a predetermined distance is ensured (the space distance is 2 mm or more, and the creeping distance is 3 mm or more) as the electrical insulation distance. Moreover, the water storage container 56 is also It is separated from the refrigerating cooler 24, and a predetermined distance is secured between the water storage container 56 and the lower surface of the refrigerating cooler % (in this case, the spatial distance is 2 mm or more, and the creeping distance is 30 mm or more). Electrical insulation distance. In addition, the electrical and "edge distance" are designed according to the provisions of the Electrical Appliances Safety Law. The lower end portion of the vertical portion 53b of the water supply portion 53 penetrates a hole formed in a lower portion of the duct constituting member 46 and a portion of the front portion of the refrigerating cooler chamber, and is inserted into the water storage container 56 from above. . . As shown in Fig. 12, the water holding container 56 is disposed at a position where it receives defrosted water dripped from the end portion 24c of the cooling cooling unit 24, particularly the coolant tube 24a, and stores it. The county material 55 of the water supply unit 53 sucks the water storage container 56 portion 50 as described above, capillary phenomenon 17 201205019. The stored water (defrosted water) is supplied to the mist to be discharged. The mist release pin (pin) 57 is provided on the horizontal portion 53a of the water supply portion 53. The mist discharge portion 5G is provided by a plurality of mists respectively constituting the projections.

Therefore, the mist releasing portion 50 is composed of a plurality of mist releasing pins (protrusions) 57 that are directed in different directions (upper and lower). Further, the mist releasing portion 5 is disposed such that the plurality of mist releasing pins (protrusions) 57 extend the horizontal portion 53a of the water supply portion 53 in the middle and opposite directions. The mist release pin 57 is placed on the upper side of the horizontal portion 53a. At this time, the four mist release pins 57 are arranged in the horizontal direction in the left-right direction. The plurality of mist discharge pins (protrusions) 57 are arranged in two stages. Each of the mist discharge pins 57 is disposed along the front wall 36a so as to be parallel to the other wall 36a of the refrigerating cooler chamber in the cold air duct 34. The mist releasing portion 50 is provided at a lower rear portion of the refrigerating chamber 3 and adjacent to the position ' of the vegetable compartment 4, and is disposed in the inner portion of the micro-freezing chamber 14. Each of the mist discharge pins 57 is formed by mixing and mixing polyester fibers and carbon fibers as conductive materials into a pin shape (rod shape), and has water absorption characteristics and water absorption characteristics. Electrical conductivity. Each of the mist discharge pins 57 carries a nano choroid. The platinum nanocolloid can be carried by, for example, immersing the mist release pin 57 into a treatment liquid towel containing a platinum nanocapsule 201205019. The bottom end portion of each of the mist discharge pins 57 penetrates the water retaining material 55. In the left end portion of the horizontal portion 53 & which is the left side of the water supply, the power receiving pin 508 constituting the power receiving electrode is provided in the μ (four) Λ type. The bottom end portion of the receiving motor 58 contacts the water retaining material % in the case 54. In the HijH52? special material tube 45 of the electric 51, the position compensation generating unit is provided with a joint-fixing guide edge::: placed. The power supply terminal 2 at the right end of the power supply unit 52 is connected to the power receiving lock 58 of the terminal structure w of the == ") (flat type). The mist generating unit A t is connected to the electric power w61 as well as known to include __ 4 : , generating a negative: i-flow of the transformer circuit of the rectifier circuit or the booster circuit voltage (~^ is applied from the negative voltage of the source device 52 from the power receiving pin%. The pin 57 is such that each of the mist discharge pins 57 is negatively charged. Further, this is grounded by a ground wire (not shown) or the like. The outer phase 2a of the water body 1 is passed through, and the water storage device is applied from the power supply device. Negative high voltage of 52. The front end of the mist release pin 57 is split at the front end (energy) ° (1) end phase water (Rayleigh splitting, Rayleigh 201205019 misty release (electrostatic atomization)

Fission), and from the front end is a microscopic image) 〇 here, the amount of generated radical) 0 thus 'has strong oxidation _ radicals from the fog release pin 57 and the fog - are released, through the role of hydroxyl radicals Can be sterilized or deodorized. At this time, the opposite 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 a corona (c〇r〇na) discharge is not generated between the discharge electrode and the opposite electrode, so that a harmful gas (ozone, or ozone) can be generated. Inhibition of nitrogen oxides, nitrous acid, nitric acid, etc., which are generated by oxidation of air in the air, is suppressed. Here, the 'fog release pin 57 (the mist discharge portion 50) can be referred to as a sterilization component discharge mechanism (also a deodorization component discharge mechanism) that discharges a free radical component (also a deodorant component). The device 48 may be referred to as a sterilization component generating mechanism (deodorizing component generating mechanism). In the front wall 36a of the refrigerating cooler chamber % constituting the rear wall of the special duct for mist 45, a mist supply port 62 is provided (see Figs. 4 and 7). The mist cooling air supply port 62 is located at a position that does not face the mist discharge pin 57 in the mist discharge portion 5, and is disposed above the power supply device 52 on the left side of the mist discharge portion 50. The rear portion of the cold air supply port 62 of the mist penetrates the heat insulating material % and communicates with the refrigerating cooler chamber 36 in the cold air duct 34, and the front portion communicates with the special conduit 45 for the fog 201205019.翕徂 / ^ The part of the cold air in the supercooled air duct 34 is supplied from the mist to the special duct 45 A for fog (see the arrow M i1 in the cold air supply port 62 of Fig. 7). The cold milk in the duct 45 is convected in the specialist pipe 45. 36ή6=above the cold air supply port 62, on the back side for the fog of the refrigerating cooler chamber, and the lower side facing the refrigerating chamber 63 is provided. 63 (refer to Figs. 4 and 7) The duct outlet port for the mist facing the refrigerating compartment is opened in the special duct 45 for mist and becomes the inside of the refrigerating compartment mist 37. The upper end portion communicates with the cold duct 34. A part of the mist generated in the special air-conditioning duct of the air-conditioning duct is supplied from the refrigerating duct 7.6 through the mist duct 63 facing the refrigerating compartment, the cold air supply port 4, and is supplied from the cold air supply port 39. The inside of the refrigerator compartment 3 (refer to the arrow B1 of FIG. 7 of FIG. 7). (The position is different from the front surface part of the duct-constituting member 46 in the dedicated duct 45. In the upper freezing chamber 2, the carboxy-freezing chamber is blown out with a mist 65 (see Figs. 4 and 7), from which the micro-photograph is taken 4. I owes an outlet 65 to supply a part of the mist into the micro-freezing chamber 14 (refer to ',,,, arrow B2 of Fig. 7). The portion of the mist is blown toward the front surface of the catheter constituting member 46 by the mist blowing port 65. 2 r is a forward-looking cylindrical shape, and the rear wall of the micro-freezing box 18 is blown upward by the mist-cutting portion 18b) (refer to FIG. 9), and is blown from the micro-freezing chamber person D 65 into the micro-freezing chamber 14 The air of the mist is mostly supplied from the incision portion of the rear upper portion of the box 18 to the micro-frozen 21 201205019; " Further, in the front surface portion of the duct constituent member 46, the egg box mist blowing port 66 (see Fig. 4) is provided on the left side of the micro-freezing room population 65, and the branch is blown out of the egg box by the mist σ 66 It is also supplied into the egg box 15 (refer to arrow Β 3 in Fig. 4). In the lower part of the right side of the special duct 45 for the mist, as shown in Fig. 5, it is assumed that the kitchen chamber is blown with the mist σ 67β, and the vegetable chamber is connected to the port 75 by the mist outlet 67, and the mist in the special duct 45 for the mist is used. The vegetables σ η 67 , the communication port 75 , the ν duct %, and the vent 77 are also supplied into the vegetable compartment 4 (see an arrow C2 in FIG. 1G ). At this time, the distance to the material supply is 62. The distance li between the cooling air supply port 62 and the vegetable to the mist outlet 67 is set to be larger than the cold air supply σ 62 and the micro; The distance L2 between 65 and 65 is located above the mist discharge portion 50 in the upper portion of the special duct 45 for fog. There is also a slight; east to the cold air supply port 68 (refer to Figure 4, Figure 6, Figure 8). As shown in FIG. 6, FIG. 8 and FIG. 9, the eastward cold air supply σ 68 is a front-facing cylinder which protrudes forward from the front surface portion of the pipe constituting member 46 and is located at the rear wall of the micro-containment box 18. The upper end is above (see Figure 9). The rear portion of the room air-conditioning supply port 68 is connected to the micro-compartment 14 through the heat-insulating material 38 and connected to the front portion of the refrigerating cooling chamber 11 s. Therefore, the portion of the cold air of the refrigerator compartment 36 is directly supplied to the micro through the microbubble to the cold air supply port 68; the east chamber 14 (refer to arrow A2 of FIG. 6, FIG. 22 201205019 8) to be slightly frozen The chamber 14 is maintained at a temperature lower than that of the refrigerating chamber 3 and the vegetable compartment 4, that is, 〇-c 〜1. Hey. Further, the heat insulating material 38 also serves as an insulating mechanism between the cooler cooler 24 and the mist discharge portion 50. Here, the structure of the water storage container 56 will be described with reference also to Figs. 15 to 17 . Fig. 15 is a perspective view showing a single body of the water storage container 56 as seen from the upper right side of the rear portion. The water storage container 56 has a rectangular container shape, and the front wall portion 56b of the front portion of the bottom wall portion 56a and the upper end portions of the left and right side wall portions 56c and 56d of the right and left side portions are set to be the same. An attachment portion 81 is provided in an upper portion of the front wall portion 56b, and the water storage container 56 is attached to the lower portion 36c of the front portion in the refrigerating cooler chamber 36 via the attachment portion 81 (see the water storage tank 56 in the drainage water compartment 56). The upper portion of the protruding portion 40e of the right front portion of the tube 4 (see FIG. 12) is provided on the front side of the bottom wall portion 56a, and the lower portion 82 is provided lower than the other portions. The rear side of the bottom wall portion 56a is further The lower end portion of the water supply portion 53 of the mist generating unit 51 is inserted into the lowest portion 82 of the water storage container 56 from above (see FIG. 8). The upper surface of the rear end portion side of the wall portion 56a is provided with a left rear sill 83 on the left side so as to be connected to the left side wall portion 56e, and a right rear portion is provided on the right side so as to be connected to the right side wall portion 56d. Wall 84. The left rear wall 83 reaches the vicinity of the center portion in the width direction of the left and right wall portions 56a. The length of the right rear wall 84 is set shorter than the left rear wall 83. The left rear wall 83 is at the right end, integrally provided There is a convex portion 83a that protrudes toward the rear. The convex portion 83a is as shown in Fig. 16 from the bottom wall portion 56. The surface 23 of 2012 is set to the back surface. Further, at the left end portion of the right rear wall portion 84, a convex portion 84a similar to the convex portion 83a is provided from the surface to the back surface of the bottom wall portion 56a. Here, the water storage container 56 is provided. In the rear portion, the drain portion 83a and the convex portion 84a are provided as a drain portion 85 which is a portion which is lower than other portions and is easily drained. On the left side of the bottom wall portion 56a of the drain portion 85, and the convex portion 83a A rib-like convex portion 86 is provided to face the convex portion 83a so as to have a slight gap therebetween. The convex portion 86 is also provided from the surface of the bottom wall portion 56a to the back surface, but the height of the upper side is set to be larger than The convex portion 83a is low. A water passage 87 having a narrow width is formed between the adjacent two convex portions 83a and the convex portion 86. The water passage 87 is formed from the bottom wall portion 56a of the drain portion 85. U-shaped continuous from the front to the back. The width of the water passage 87 is set to about 1 mm to cause capillary action of water. Moreover, 'on the right side of the bottom wall portion 56a in the drain portion 85, to A rib-like convex portion 88 is provided to the convex portion 8 so as to have a slight gap between the portions 84a. The convex portion 88 is also provided from the surface of the bottom wall portion 56a to the back surface, but the height of the upper portion is set to be lower than the convex portion 84a. Between the adjacent two convex portions 84a and the convex portion 88, the same is formed. Further, in the drain portion 85, a water passage forming member 9A is attached between the convex portion 86 and the convex portion 88 at the rear end portion of the bottom wall portion 56a. As shown in FIGS. 17 and 18 (&) and FIG. 18 24 201205019 (b), the water passage forming member 90 has a U-shaped cross section and has a U-shaped water passage 91 inside, and is attached to the bottom wall portion. The rear end portion of the 56a forms a U-shaped water passage 91 continuous from the surface to the back surface of the bottom wall portion 56a of the drain portion 85. The height (depth) of the water passage 91 is set to about 丨 mm to cause a capillary phenomenon of water. The water passage forming member 9 is stopped by the pair of elastic engagement claws 92 provided at the rear end portion of the bottom wall portion 56a. At this time, in the drain portion 85 of the water storage container 56, the two ships in the width direction have a pass tree 87, and the water side 91 is provided in the central portion of the money side (10). Further, on the back surface (lower surface) of the rear end portion side of the bottom wall portion 56a, the front side of each of the water passages 87, 91 is projecting downward with a rib-like projection as shown in Fig. = waters, and is disposed in the drain pipe. In the upper state of the crucible 4, the drain portion 85 of the container 56 is located at the right portion of the row portion 8〇, and the portion of the paper that is in contact with the refrigerating drain pipe 4, that is, the heat-conducting fin is removed, and the end portion is torn. The refrigerating compartment t is the upper part, and the cooling air is cooled by the refrigerating air supply and refrigerating cooler 24 as shown by the hollow arrow in Fig. 1, and the air blowing action is mainly supplied to the refrigerating compartment d as a cold air supply port 39. The conduit 37 is supplied from the micro-small; the east chamber is directly supplied to the micro-second by the cold air supply port 68: 25 201205019 arrow A2). After being supplied into the refrigerating compartment 3 and the micro-chambers μ, 7 is rolled to contribute to the cooling of the stored matter such as food, as shown by the arrow C1 of the above-mentioned: 'flowing out from the ventilation D74.a, 74b to the passage 1 73 'Replenishment in the left direction and the right direction, on the upper side of the chamber 4, the left and right outer surfaces of the casing 12 are supplied to the vegetable = dried, and a part of the cold air in the i-connected fin 14 is as shown by the arrow C2 of the foot communication port 75 of FIG. Pass through the V-catheter 76 and from the vent 77 to the 4th. After being cooled to the vegetable compartment 4 (10), the cold storage of the vegetables is sucked from the suction port 43 to the side of the cold == 35 side, and the refrigeration cooler 24 performs the cycle of = again. For example, the portion of the cold air in the refrigerator compartment 3 and the vegetable compartment 4 cooler chamber 36 is supplied as an arrow A in FIG. 45 inside =, r = L45 straight cold air hits the pipe constituting member 46; i face, thereby forming convection in the fog duct 45 and expanding the table. At this time, when the electrostatic atomizing device 48 is driven, the fog Production = a mist release pin 57 is discharged as described above. The portion of the mist discharged from the mist release pin 57 is shown by the arrow in Fig. 7, and the cold air of the pair is used to blow the gas from the refrigerator. The mist duct 63 and the cold air supply duct 3 are supplied to the refrigerating compartment 3 in the room. ^ 37, and from the cold air supply port and the fog released from the mist release pin 57 - as shown in Figure 26 and Figure 26 201205019 7 arrow B2, from the financial office with a mist blown out of the inside: its plum box It is also supplied from the egg box to the egg 15 by the mist blowing outlet 66. The dish is placed in the vegetable room 4 from the bottom right vegetable to the user outlet 67 through the communication port 75, ν catheter%. Therefore, in the present embodiment, it is possible to supply a plurality of supply targets such as the cold age 3, the financial chamber 14, the egg box 15, and the vegetable compartment* to the mist in the magical duct of the special duct, and it is expected that these supply targets can be excluded. The effect of bacteria or deodorization, and the moisturizing or preservation of vegetables and the like can also be expected. In addition, in the state where the supply of the coolant to the storage cooler 24 is stopped, the defrosting of the cold storage section is driven by the chiller. The air in the (refrigeration chamber 3, the vegetable compartment*, and the microbeam chamber 14) is circulated by the cold air duct 34. When the air in the storage compartment of the refrigerating temperature section is circulated through the cold air duct %, the temperature of the refrigerating material 11 24 becomes a plus temperature, whereby the temperature of the refrigerating cooler 24 rises to perform defrosting. The portion of the defrosted water dripped from the refrigerating cooler 24 at the time of defrosting of the refrigerating cooler 24 is taken up and stored by the water storage container 56 of the electrostatic atomizing device 48, and most of the remaining defrosting water is as described above. After being taken up by the drain pipe 4, it is guided from the drain port 41 to the defrost water evaporating dish 28 and evaporated. Here, the defrosted water received and stored by the water storage container 56 is sucked by the water retaining material 55 of the mist generating unit 51 and supplied to the mist discharge pin 57, and is discharged as mist from the mist discharge pin 57. Therefore, the consumption of the water storage container 56 is sometimes exceeded by the amount of the defrosted water dripping from the refrigerating cooler 24 to the water storage container 56. At this time, in the present embodiment, the water stored in the water storage container 56 is dropped onto the drain pipe 40 as follows. That is, when the rear end portion of the water surface stored in the water storage container 56 reaches the drain portion 85, the water in the water storage container 56 enters the water passage through the capillary phenomenon of the water passage 87 or the water passage 91 formed in the drain portion 85. 87 and 91 are wound from the surface of the drain portion 85 to the back surface by the water passages 87 and 91, and are dropped into the lower row 40 along the projection 93 on the lower surface of the bottom wall portion 56a. At this time, since only the amount of water causing the capillary phenomenon enters each of the water and 87, 9^, the water does not continuously flow out, but the __drop-drop is dripped continuously. At this time, it is preferable to apply a treatment for reducing the surface of the water in the vicinity of the water passages 87 and 91 or a solid aqueous treatment, or to make the water in the water storage container 56 easy to pass through the capillary phenomenon 87, 91. Inside. In order to make the Confucian wetness good, for example, paper can be used to coarsely mash the surface of the member. However, when the water passages 87 and 91' of the present embodiment are not formed in the drain portion 85 and the rear end portion of the bottom wall portion 56a is a simple inclined plate shape or a straight wall, the water storage device is used. When the amount of water stored in 56 increases, it will accumulate due to the surface tension of ^. The amount of water capacity H 56 is greater than or equal to a certain fixed amount '7jC will be - the airflow out of the 'water storage container%

40 will be connected by water in an instant. 〃 S 28 201205019 When the negative high voltage of the power supply device 52 is applied to the mist generating unit 51 via the power supply terminal, the power supply terminal 61 and the refrigerating cooler 24 may pass through the water in the water retaining material 55 or the inside of the water storage container 56. The water, the water flowing out from the water storage container 56, and the water adhering to the inner surface of the drain pipe 4 are electrically connected, and a negative high voltage is applied to the refrigerating cooler 24 to cause the refrigerating cooler 24 to be charged. In this regard, in the present embodiment, as described above, when the water in the water storage container 56 is discharged from the drain portion 85, the water is dripped continuously to the drain pipe 4 through the water passages 87, 91 by the capillary phenomenon. Therefore, it is possible to reliably prevent the water storage container 56 and the drain pipe 40 from being instantaneously connected to each other by water, and it is possible to reliably prevent the negative high voltage of the power source device 52 of the electrostatic atomization device 48 from being applied to the refrigerating cooler 24. Further, at this time, the partition portion 80 is provided on the upper surface of the bottom wall portion 4a of the drain pipe 4A, and the drain portion 85' of the water storage container 56 is disposed on the right side of the partition portion. The partition portion 8 prevents the water discharged from the drain portion 85 from being connected to the water on the front surface of the rear wall portion 40b that is in contact with the heat transfer fins 24b of the refrigerating cooler % in the drain pipe 4'. Thereby, it is also possible to prevent the negative high voltage of the power supply device 52 from being applied to the cooling cooling H 24 . At this time, the special partition portion (10) is inclined, so that the defrosted water can be prevented from adhering to the side surface 8〇d which is the lower side of the inclined side (refer to Fig. 14), so that the side surface 8〇d can be prevented from being wetted by water. Thereby, since the portion where the water does not wet can be formed on the partition portion 80, the portion is effective for electrical insulation, and the water discharged from the drain portion 85 can be more reliably prevented from following the drain pipe 40. The refrigerating cooler % 29 201205019 is connected to the water on the front surface of the rear wall portion of the rear wall portion of the lion. ===;: The effects as described below can be obtained. The defrosting of the water damper is applied to the defrosting device, and the power supply device 52 of the electrostatic atomizing device 48 is used to store the water storage container 56. In the refrigerator, the upper surface of the bottom wall portion 4〇a of the 排 ί ί 〇 设置 设置 设置 设置 设置 设置 设置 设置 设置 设置 设置 设置 设置 设置 设置 设置 容器 容器 容器 容器 。 。 。 。 。 。 。 。 . The water in each of the water and the refrigerating cooler 24 is continuously separated from the drain portion 85 of the water storage container 56 by the partition portion 8 to prevent the water from being connected to the cold charging material for refrigerating (4). The right portion 8 of the partition portion 8 that is provided in the refractory tube 40 is the right end portion 24d which is the end portion of the Γ5, and the drain pipe of the water storage container 56 is connected to the drain. At this time, the partition portion 80 is extended from the right portion 80c. Therefore, the partition portion 80 is long in the horizontal direction from the drain hole λ drain port 41 to the drain: Before and after the inside:: Right = The water flowing through the front side in the drainage squad 40 flows through the rear side: the water does not flow 201205019 to the drain 41. Therefore, it is possible to reliably prevent the water dripping from the drain portion 85 from being connected to the water flowing through the rear side of the drain pipe 40. Further, since the partition portion 80 is inclined, it is possible to prevent the defrost water from adhering to the lower side surface 8〇d on the inclined side as described above, and it is possible to prevent the side surface 80d from being wetted by the water. Thereby, the month b is sufficient to form a portion where the water does not get wet on the partition portion, so that it is possible to surely prevent the water discharged from the drain portion 85 from coming into contact with the guide piece of the refrigerating cooler 24 in the drain pipe. The water on the front surface of the rear 4〇b is connected. + The following structure is adopted: in the drain portion 85 of the water storage container 56 that receives the phase water and is stored from the refrigerating cooler 24, the water passages 87 and 9 are provided from the surface of the f portion 85 to the back surface. Bu water storage container 6 = stored water _ Maosaki now (four) through the tree 87, μ not continuously drip to the drain pipe 4 〇. In the refrigerator having the water storage capacity 11 56 constituting the water storage portion and the non-connecting water pipe 4 ', the water can be discharged from the water storage container 56 to the drain pipe 4〇. The water receiving portion receives the water structure from the water storage container, and discharges the water from the drain portion 85 of the water storage container 56. Therefore, the water does not continuously flow out, and it is possible to prevent the application of the material phase cooling H24 from applying the (four) high voltage. 31 201205019 In the drain portion 85, the water passage 87 on the left side is formed by two adjacent convex-M3a and convex 86, and the water passage on the right side is formed by the adjacent|vertical portion 84a and the convex portion 88. The U-shaped water passage 87 can be formed with a simple structure. Further, in the drain portion 85 t, the water passage 91 at the center portion is formed by the U-shaped water passage forming member 90. Therefore, the U-shaped water passage 91 can be formed in a simple structure. In the drain portion 85, the water passage 87 is formed in the left and right sides of the drain portion 85 in the width direction. Therefore, even if the water storage container 56 is in an inclined state, the at least one water passage 87 can be effectively exerted. effect. The water used in the electrostatic atomizing device 48 is a cold-storage water stored in the storage container of %, so that the water supply to the water storage container 56 is automatically performed, so that the user (user) can be omitted. The time for water supply. ^, The cold of this embodiment; the East refrigerator adopts a cold ring that has a cooling element 冷 and a cooling double n ^ (evap〇) side. Here, as the real money, the lion double evaporator method of cold _ Lai cold; the East refrigerator's cold Kangke material 25 peripheral temperature or single button | | way cold; East refrigerator cooler peripheral temperature in addition It will become a positive temperature due to the heating of the defrosting heating H, but will always be maintained at -20 except during defrosting. (: The following temperature. Assuming that a water storage container is provided below these coolers, even if the water storage capacity receives and stores the defrost water during the defrosting of the crotch, the water in the water storage container is transcribed into ice. Therefore, there is a problem that it is difficult to stably supply water to the mist discharge unit 50 in 201205019. In this regard, in the present embodiment, two cooling units including the refrigerating cooler % and the freezing cooler 25 are provided. In the double-evaporator type refrigerator of the double evaporator type, the water storage container 56 is installed in the refrigeration cooler 24. In the evaporator type refrigerator, the periphery of the refrigerator cooler 24 Although it is a negative (rrnmis temperature) in the cooling operation of the refrigerating cooler 24, it is still much higher than the temperature of the refrigerating cooler 25, and when the defrosting of the refrigerating cooling H 24 is performed, the cold air is supplied by the cold. The air circulation of the fan is close to the vicinity of the temperature of the refrigerating compartment 3. Therefore, the water placed in the water storage container 56 below the refrigerating cooler 24 is hard to freeze, and is easily melted even if it is frozen. Thus, able The mist discharge portion 5G is stably supplied to the mist discharge portion 5A. The mist discharge portion 5G of the electrostatic atomization device 48 is composed of a plurality of mist discharge pins (projections) 57 that protrude in different directions. In the case where the protruding direction of the projection is only one-way, the supply direction of the mist can be set to a plurality of directions, and the supply range of the mist can be widened. The mist discharge portion 50 adopts the mist discharge pin ( The protrusion 57 has a structure in which the horizontal portion 53a of the water supply 4 53 is sandwiched in the middle ❿ in the opposite direction, and the mist can be made to widen the supply direction of the widened mist in the opposite direction to the upper side and the lower side. The horizontal portion 53a and each of the mist discharge pins 57 are disposed along the front wall 36a so as to be flush with the front wall 3 of the refrigerating cooler chamber 36 in the cold air duct 34, thereby enabling front and rear 33. 201205019 The thickness is reduced in thickness. The mist release pin (protrusion) 57 is arranged in two upper and lower sections to achieve compactness. The mist discharge portion 5 is configured to release a plurality of the mist discharge pins (protrusions) 57. a knot arranged in a row 'The amount of mist can be increased, so that the supply range of the mist can be further widened'. Further, the thickness can be reduced. The water supply unit 53 has a curved portion 53c' which is stored under the curved portion 53c. The water storage container 56 can supply the water stored in the water storage container 56 to the curved portion 53c. Thereby, the water of the water storage container 56 can be supplied to the mist discharge pin 57 via the curved portion 53c. The mist discharge portion 50 is interposed therebetween and disposed on the opposite side of the curved portion 53c. Thus, the power supply device 52 can be further moved away from the water storage container 56°, and the power supply device 52 and the mist generating unit 51 can be connected to the cold air conduit 34. The front wall 36a of the refrigerating cooler chamber 36 is disposed in parallel with the front wall 36a, and the electrostatic atomization device 48 can be made thinner in the depth direction. The mist discharge pin (protrusion) 57 in the mist discharge portion 50 of the electrostatic atomizing device 48 is disposed along the cold air duct 34. Thereby, the depth dimension of the electrostatic atomization device 48 in the front-rear direction can be suppressed, and the thickness can be reduced. Along with this, the reduction in the internal volume of the refrigerator can be suppressed. In the front portion of the cold air duct 34, a cold air supply port 62 for supplying cold air into the special duct 45 for mist is provided, and the mist discharge portion 50 of the electrostatic atomizing device 48 is disposed in front of the cold air duct 34. Thereby, the cooling air supplied from the mist cold air supply port 62 to the mist guide 34 201205019 tube 45 can be used to disperse the mist discharged from the mist discharge unit 50 to a distant place. The mist cooling air supply port 62 and the mist releasing portion 50 (the mist releasing pin 57) are disposed at positions shifted to the left and right so as not to face each other in a direction different from the opposing position. Therefore, the cold air supply port 62 for fogging is provided. The cooling air supplied into the special duct 45 for fog is not directly blown to the mist discharge unit 5 (the mist discharge pin 57). Thereby, the phenomenon that the mist discharge pin 57 is directly dried by the cooling air from the mist cold air supply port 62 can be suppressed. The refrigerator main body 1 includes a special duct 45 for mist that houses the electrostatic atomizing device 48 having the mist releasing portion 50, and a supply target for the mist generated by the mist releasing portion 50 is provided in the special duct 45 for mist. Different multiple mist blowing outlets. Specifically, the plurality of mist blowing ports are referred to as a mist blowing Q 6% in the refrigerator compartment, a mist blowing outlet 65 for the freezing chamber, a mist blowing outlet 66 for the egg box, and a mist blowing outlet 67 for the vegetable compartment. Thereby, the mist generated in the special duct 45 for mist can be supplied to the four supplies of the three, the microbeam chamber, the egg box 15, and the vegetable compartment 4: 臧^ widening the supply of the mist, and the effect of expanding the mist . - 'The micro-freezing chamber 14 in the foggy supply target, the egg box 15 ^ have the micro & 18, the egg box 15, the vegetable box (the lower box f "box 12), and the mist can be supplied to these boxes well At the time of the upper part, a plurality of mist blowing outlets (refrigerated mist blowing outlets to the mist blowing outlets 65, egg boxes blowing with mist π « a micro-frozen outlet 66 and vegetable compartments with fog blowing 35 201205019 mouth ^7) Since the discharge portion 50 is around the center, the mist discharged from the mist discharge portion 50 can be favorably supplied to each of the mist blowing outlets. The λ mist generating unit 51 has a mist discharge pin (projection) 57 and a special guide for the mist 45 In the evening, the mist blowing outlet (the mist blowing outlet 63a for the refrigerating compartment, the micro-freezing chamber, the blowing outlet 65, the mist blowing outlet 66 for the egg box, and the mist blowing outlet 67 for the vegetable compartment) are disposed at a position opposite to the mist releasing pin 57. (The position that is not directly facing) is 'even' even if there is a finger or foreign matter inserted into the special duct 45 for the mist from the mist outlet, it can prevent them from directly contacting the mist discharge pin 57', thereby ensuring safety. The duct is constructed of a special duct 45 for fog Since the member 46 is detachable, the maintenance of the mist generating unit 51 and the like can be easily performed. (Second Embodiment) Fig. 19 shows a second embodiment. The second embodiment is different from the above-described first embodiment. The large surface portion 95 is similar to the upper surface of the bottom wall portion 40a of the partition ΛΑ UV and the water tube 40 in the first embodiment, and the sub-M 95 is below the refrigerating material H 24 and is drained. The wall of the tube 40 t that is in contact with the refrigerating cooler 24, that is, the front surface of the rear wall portion 40b is provided on the rear wall portion 40b in a manner of being protruded toward the front. 0 is viewed from the front along the left and right partition portions 95. According to this configuration, when the chilling cooler 24 is defrosted, the chiller cooler 24 # defrosting water drops γ along the front surface of the rear wall portion (four), 36 201205019 Table = 4; / ® and the front surface 40g of the back surface portion 95b of the back surface 95b, I and the surface 95b and the front surface, therefore, the partition portion 95 can also be separated to avoid the water storage capacity ;| The water dripping from the drain portion 85 of 56 is connected to the cooler 24 from the refrigeration, so even if Water capacity!! 56 7 Μ 霜 水 水 「 「 「 「 「 「 「 「 「 施加 施加 施加 施加 施加 施加 施加 施加 施加 施加 施加 : : : : : : : : : : : : : : : : : : : : : : : : : Third Embodiment FIG. 20 and FIG. 21 show a third embodiment. The second embodiment differs from the second embodiment described above. That is, the front surface of the rear wall portion of the partition portion 疋^#水官40 is located. The chiller chiller 24 is provided to receive the defrosting water of the refrigerating cooler 24. The partitioning portion α is a portion other than the end portion 24e of the right side 24a except for the coolant in the refrigerating cooler μ. In the range of the defrosting water, the left and right direction and the size of the front and rear directions are set. Further, a drain port 97 is provided in the bottom wall of the partition portion 96, and the drain port 97 is inserted into the drain port 41 of the drain pipe 40 from above. At this time, the drain port 41 of the drain pipe 40 and the partition portion % are in a drooping state. Each of them is formed into a rail structure, and almost all the defrosting water other than the right end portion 24C of the defrosting water generated by the cold cooler 24 is taken up from the drain port 97. And the drain port 41 is discharged to the defrosting water evaporating dish 28 of the machine to 26. 37 201205019 π The knife partition 96 can also be separated to avoid the connection between the water storage container and the chilled water from the refrigerating cooler 24, so that the money stored in the water container 56 plus (four) high voltage can also The anti-pressure is applied to the refrigerating cooler 24, so that the refrigerating cooler 24 can be prevented from being negatively charged. (Fourth embodiment) Fig. 22 shows a fourth embodiment. The first embodiment differs from the first embodiment described above in that the bottom wall portion 40a of the drain pipe is provided with a third drain port ι located below the refrigerating cooler 24 and located at the bottom. The second drain port 1〇1 below the water container 56. Further, on the upper surface of the bottom wall portion 40a, the right end portion 24d of the heat transfer fin 24b of the refrigerating cooler 24 and the water storage container 56 are provided upward. The protruding rib-shaped partition portion 1〇2. On the bottom wall portion 40a, the left side of the partition portion 1〇2 is inclined toward the i-th drain port 100. The right side of the partition portion 1〇2 faces the second drain port 1〇. According to this configuration, almost all of the defrosted water except the end portion 24e on the right side of the coolant pipe 24a in the defrosted water generated by the cold cooling H 由 is separated by the partition 1 in the drain pipe 40. The left side of 2 is taken out and discharged from the first drain port 100 to the outside of the refrigerator. The defrosted water dripped from the right end portion 24c of the coolant pipe 24a is mainly taken up and stored by the water storage container 56, and the remaining portion is drained. The tube 4 is received by the right side of the partition 102 and discharged from the second drain port 1〇1 to 38 201205019 The water dripping from the water storage 56 is taken up on the right side of the drain and is discharged from the second drain 1 〇 1 & ^ partition 102 whether it is the water over the phase through the first drain σ * ° In addition, the water is discharged to the mechanical room 霜 ΐ ΐ = 82. The drain port 101 Therefore, the partition 102 at this time can also drip the water from the water container 56 and from the cold to avoid reading, so even for the storage The defrosted water phase of the water container (4) 24 can also prevent the μ electric test wire from reaching; the high temperature of the twisted water is cooled negatively by the cooler 24 of the refrigeration. ^ 24 thus the month b is sufficient (the fifth embodiment) and the upper = 3 In the fifth embodiment, the lower part of the lion is formed to have a rearward direction (Fig. 23 in the middle, and the rear part of the rear wall is 5; Part 1〇6. According to this structure, in the drain pipe == frost:=:=, the bottom; the partition 1.6' so the partition protrudes to the other side of the water storage container 56 dripping ·Μ ώ The boring tool is prevented from being connected, so that even the defrosted water phase of the cooler 24 for storing the water storage container can prevent the high voltage of the water stored in the high mine (4), and the refrigeration is stopped. The cooler is negatively charged to the refrigerating cooler 24, so that it can be prevented as a water storage portion, and only the voltage of 2012 20121919 can be applied to the stored water for the atomizing device, and is not limited to the water storage of the electrostatic atomizing device 48. When the container ST is atomized by using an ultrasonic vibration element, the second St may be provided as needed, and the water passages 87 and 91 of the water storage container 56 may not be provided. In a refrigerator including a tube for receiving defrosting water generated by defrosting and a water storage portion for storing the applied water, a partition is provided in the tube, and the partition is partitioned to Avoid (10) the water dripping from the water is connected to the defrosting water from the cooler. Thereby, even if the water dripped from the water storage portion continuously flows down, the partition portion can be used to prevent the water from being electrically connected to the defrosted water from the cooler, thereby preventing the voltage from being applied to the cooler. (Sixth embodiment) Figs. 24 and 25 show a sixth embodiment. The sixth embodiment is different from the above-described first embodiment in that a water collecting portion for collecting defrosted water is provided in the coolant pipe 24a of the refrigerating cooler 24. That is, as shown in Fig. 24 and Fig. 25, the above-described refrigerating cooler 24 has a configuration in which the coolant tube 24a which is configured to be cold is circulated in the vertical direction and passes through the plurality of heat transfer fins 24b in a meandering manner. The coolant tubes 24a that are serpentinely passed in the up-and-down direction are arranged side by side in a plurality of rows (two columns) along the front-rear direction, and the plurality of heat-conducting fins 24b are extended along the air-cooling duct 34. The directions (the vertical direction in FIG. 1) are arranged in a direction substantially orthogonal to each other (the left-right direction of the refrigerator body 1). The air flowing through the cold air duct 34 passes between the plurality of heat radiating fins 24b constituting the refrigerating cooler 24 201205019, thereby being cooled by the refrigerating cooler 24. The water storage container 56 is disposed below the refrigerating cooler 24 and at a position facing downward from the first row coolant pipe 24a on the front side of the refrigerating cooler 24. Further, in the same manner as the refrigerating cooler 24, the refrigerating cooler 25 employs a structure in which a coolant tube is passed through a plurality of heat transfer fins. An overflow portion 156a which is set lower than the other portion is formed in the upper portion of the front end portion on the rear side of the water storage container 56, and when the water stored in the water storage container 56 overflows, it overflows from the overflow portion 156a. The water storage container is allowed to be located above the drain & 40, and the overflow water from the overflow portion 15 is taken up by the drain pipe. In addition, a part of the coolant pipe 24a (the front side of the refrigerating cooler 24 cools the lungs 69) ± a plurality of (three) water collecting materials made of, for example, a resin material such as polypropylene Ring (rmg) 171 (equivalent to the catchment). An annular member through which the water collecting ring 17 passes. These water collecting rings 171 mainly have Wei as a water control portion along the frost water. For example, the structure of the tree 171 may be separated from the water collecting ring 171 by a container of the _ or c ring structure, and the predetermined distance may be maintained in the water storage container (for example, the spatial distance is 2 mm or more. The surface distance is 3G _ or more) so that the distance is on a part of the coolant tube 24a. Therefore, the defrost water can be turned to the water collecting ring 171 to drip. The capsule water % 171 is concentrated. Therefore, in the structure in which the size of the water storage container 56 201205019 is reduced in order to secure the electrical insulation distance, the defrosting water can be efficiently dropped onto the water storage container 56, so that The amount of water stored in the defrosted water in the water storage container 56 is sufficiently ensured, and the amount of supply of the defrosted water to the electrostatic atomization device 48 can be sufficiently ensured. Further, since the water storage container 56 is spaced apart from the water collecting ring pi, the water storage container 56 connected to the mist discharging portion 50 to which the high voltage is applied can be maintained and the outer case 2a accessible to the user (possibly linked to the outside) The refrigerating cooler 24) of the tank 2a is electrically insulated. (Seventh Embodiment) Fig. 26 shows a seventh embodiment. The configuration of the water collecting portion of the seventh embodiment is different from that of the sixth embodiment. In other words, the water collecting plate 181 (corresponding to the water collecting portion) is a plate-shaped member made of a resin material (for example, polypropylene), and has two cs at the upper portion thereof, and a portion 181a. These C ring portions 181a are respectively embedded in the cooling. A part of the agent tube 2乜 (a portion folded in the front-rear direction in the lower portion of the refrigerating cooler 24). Further, the water collecting plate 181 has an inclined portion 181 at a lower portion thereof, and the inclined portion 181b is gradually inclined downward from the rear portion toward the front portion. The water storage container % faces the lowermost end portion of the inclined portion 181b of the water collecting plate 181 from below. Further, the water storage container 56 is spaced apart from the water collecting plate 181, and a predetermined distance is secured between the water storage container 56 and the water collecting plate 181 (in this case, the spatial distance is 2 mm or more, and the creeping distance is 30 mm or more). As an electrical insulation distance. According to the configuration including the water collecting plate 181, not only the i-th column coolant pipe 24a on the front side of the refrigerating cooler 24 but also the second column in the rear side of the refrigerating cold cooler 24 201205019 The coolant pipe 24a collects the defrosted water and causes the defrosted water to drip concentrated from the lowermost end portion of the water collecting plate 181. Therefore, in the structure for reducing the size of the water storage container 56 in order to secure the electrical insulation distance, the defrosting water can be efficiently dropped to the water storage container 56, so that the inside of the water storage container 56 can be sufficiently ensured. The amount of defrosting water stored in the electrostatic atomizing device 48 can be sufficiently ensured by the amount of water stored in the defrosting water. (Eighth Embodiment) Fig. 27 shows an eighth embodiment. The configuration of the water storage unit according to the eighth embodiment is different from that of the first embodiment described above. That is, the water storage container 191 (corresponding to the water storage portion) in place of the above-described water storage container 56 is made of a resin material (for example, polypropylene). The water storage container is integrally provided with a support frame portion 192, and further, a water collection tube portion 193 is integrally provided on the support frame portion 192. These support frame portions 192 and water collection tube portions 193 are also made of a resin material (polyolefin). The water collecting portion 193 has a water receiving portion 1 extending in the substantially front-rear direction and a secret groove portion extending in a substantially upper and lower direction. The water tank portion 193a is a groove-shaped portion which is inclined downward from the rear portion toward the shovel portion in the lower portion of the portion of the coolant pipe 24a (the portion which is folded in the front-rear direction in the lower portion of the refrigeration unit 24). The eight-drop groove portion 193b is a groove-shaped portion that is connected from the water-sink portion 193a. The other end portion (lower end portion) is tapered toward the respective members 191 on the one hand. In addition, the water storage container 191 is spaced apart from the water collection tube portion 193, and a predetermined distance (space) is ensured between the water storage device 191 and the water collection official portion 193 (particularly, the front end portion of the drip groove portion (9) (4)). The distance is 2〇imn or more, and the distance along the surface is ^omm or more) as the electrical insulation distance. Further, the water collection pipe portion 193 is separated from the refrigerating cooler 24 and the coolant pipe 24a. According to the configuration including the water collection tube portion 193, not only the first column coolant pipe 24a on the front side of the refrigeration unit 24, but also the second column on the rear side of the refrigeration cold P device 24 can be used. The coolant pipe 24a collects the defrosted water and causes the defrosted water to drip from the lowermost end portion of the water collection pipe portion 193 (the front end portion of the drip chamber 193b). Therefore, in the structure in which the water storage container 191 = size is reduced in order to secure the electrical insulation distance, the defrosting water can be efficiently dropped to the water storage capacity =, so that the defrosting water in the water storage container 191 can be sufficiently ensured. In the stored water, the supply amount of the defrosting water to the electrostatic atomizing device 48 can be sufficiently ensured. In addition, since the water collection tube portion 193 is configured to be disposed in the water storage container 191, the water storage container 191 and the water collection tube portion 193 (particularly, the tip end portion of the dropping groove portion i93b) can be accurately ensured. Electrical insulation distance. (Ninth Embodiment) Fig. 28 shows an eighth embodiment. The configuration of the water collecting portion of the eighth embodiment is different from that of the sixth embodiment. In other words, the water collecting plate 200 (corresponding to the water collecting portion) is a plate-shaped member made of a resin material (for example, polypropylene), and the bottom end portion (right end portion in Fig. 28) is fixed to the inner box 2b, and its front end The portion (the left end portion in Fig. 28) serves as the connecting portion 200a. 44 201205019 The portion of the joint portion 2GG to the cooling portion 24a (the portion on the rear side in the portion folded in the front-rear direction of the lower portion of the refrigerating cooler 24). Further, in the lower portion of the water collecting plate 200, a plurality of (upper and lower) water collecting plates 201a and 2〇ib are provided. These water collecting plates 2〇1a and 11b are respectively formed into a plate shape, and are inclined downward toward the water storage container 56. The water collecting pipe 20ib in the lower stage is formed to be longer than the water collecting plate 201a of the upper stage. Further, the front end portion of the water collecting plate 2 of the lower stage is spaced apart from the water storage container 56. In particular, the defrosting water of the second column coolant officer 24a from the rear side of the refrigerating cooler 24 can be set according to the configuration including the water collecting plate 2〇〇 and the water collecting plates 2〇1a and 2〇1b. The water plate 2 and the water collection plate 2 are collected and collected into the water storage container 56. Therefore, in order to secure the electrical insulation distance, the size of the water storage container % is reduced, and in the structure, the defrosting water can be efficiently dropped to the water storage container 56 to sufficiently ensure the defrosting in the water storage container 56. The amount of water stored in the water can further sufficiently ensure the supply amount of the defrosting water to the electrostatic atomizing device 48. Further, since the water collection pipes 2a, 2b are provided in a plurality of stages, it is difficult to form a water film between the water collection pipes 201a and the space, and electrical insulation between the refrigeration cooler 24 and the water storage container 56 can be ensured. status. In addition, the water collecting plate is not limited to the upper and lower sections, and may be configured as, for example, upper and lower two & four-segment shirts. ^ Also, the water collecting plate can be formed as the upper portion is larger, and the smaller the lower portion is. Therefore, the water dripping from the upper water collecting plate is difficult to collect with the lower section of the water. The water is connected to prevent further formation of water between the water collecting plates, 4 which is sufficient to ensure the electrical insulation of the refrigerating cooler 24 from the water storage container 56. (Tenth embodiment) Fig. 29 shows a tenth embodiment. In the first embodiment, the structure of the Hercules unit 111 in the static crane unit (10) constituting the mist generating device is different from that of the first embodiment. The mist generating unit 7C 111 includes a mist releasing portion 112 and a water supply portion 113 that supplies moisture to the mist discharging portion 112. The water supply unit 113 has a circular portion ll3a that is circular as viewed from the front, and a vertical portion 113b' that extends downward from the _ portion U3a, and is made of the same material as the water-retaining material: 55 (see the i-th embodiment). The water retaining material 115 is housed in the box ΐ4. The lower end portion of the vertical portion 113b penetrates the lower portion of the duct constituent member and the front portion 36b of the refrigerating cooler chamber 36 (refer to the gate 8), and is inserted into the water storage container provided in the refrigerating cooler chamber 36 from above. %Inside. The circular portion 113a and the vertical portion of the water portion 113 are disposed along the front wall 36a in a flush manner with the front wall 3 of the refrigerating cooler chamber 36 in the & air conduit 34. The mist releasing portion 112 is composed of a plurality of mist releasing pins that respectively constitute the projections. The mist release pin 57 is radially provided in the circular portion U3a. Therefore, the "fog releasing portion 112" is composed of a plurality of mist releasing pins 57 (projecting portions) that protrude in different directions. The bottom end portion of each of the mist discharge pins 57 is passed through the case 114 and is in contact with the water retaining material 115. Each of the mist discharge pins 57 is also provided in a left portion of a circular portion _ which protrudes along two = 2 so as to be parallel to the front wall 36a of the cold air guide, and a dog out 卩U3e is set at the protruding portion 113e. In the upper state, the power receiving pin 58 is provided in a state of being protruded to the left. The power supply terminal 61 based on Quarley. Further, the electric pin 58 is connected to the power supply unit 52. In this configuration, the water stored in the water storage container 56 is sucked by the water retaining material 115 by the capillary f phenomenon, and is supplied to the respective mist discharge pins 57. Then, the negative high voltage from the power supply unit 52 is applied to the respective mist discharge pins 57 from the power receiving pin 58 via the moisture of the water retaining material 115, whereby a fine mist is released from each of the mist discharge locks 57. In the same manner as in the third embodiment, the mist is discharged from the plurality of mist blowing outlets (the refrigerator compartment mist outlet 63a, the microfreezer mist outlet 65, the eggfill mist outlet 66, and the vegetable compartment mist outlet). 67) A plurality of supply targets are supplied to the refrigerating compartment 3, the micro-freezing compartment 14, the egg cartridge 15, and the vegetable compartment 4. Further, since the mist release pin 57 is arranged radially, it is preferable to release the mist in more directions than in the case of the first embodiment (the third embodiment). Figs. 30 and 31 show Eleventh embodiment. In the third embodiment, the structure of the drain portion and the water passage in the water storage container 56 is different from that of the first embodiment of the invention. The left rear wall 83, the convex portion 83a, the convex portion 86, the right rear wall 84, and the convex portion 84a in the first embodiment (see FIG. 15) are not provided on the rear side of the bottom wall portion 56a of the water storage container 56. The convex portion 88, the water passage forming member 9A, and the pair of elastic engagement claws 92, and the rear portion of the bottom wall portion 56a have a flat plate shape that is inclined rearward and upward. A drain portion 195 is defined between the left side wall portion 56c and the right side wall portion 56d at the rear end portion of the bottom wall portion 56a. Further, a water passage 196 formed of a concave groove is provided on both left and right sides of the rear end portion of the bottom wall portion 56a on both sides in the width direction of the drain portion 195. The water passage 196 is also U-shaped continuously from the surface to the back surface of the bottom wall portion 56a. The width dimension and depth dimension of the water passage 196 are set to about 1 mm' to cause capillary action of water. In this configuration, when the water stored in the water storage container 56 flows out, the water passes through the water passage 196 from the surface of the bottom wall portion 56 & to the back surface by capillary action, and is discontinuously dropped from the projection 93 of the lower surface. It falls and is taken over by the drain pipe 40. In such a configuration, substantially the same operational effects as those of the first embodiment can be obtained. In particular, the width of the drain portion 195 is wider than the width of the drain portion 85 of the first embodiment. However, since the water passage 196 is provided on both sides in the width direction of the drain portion 195, even if the water storage container 56 is oriented The water passage 196 can also function effectively in a state where the left and right directions are inclined. Since the water passage 196 of the eleventh embodiment is constituted by a concave groove, the U-shaped water passage 196 can be formed with a simpler structure. 48 201205019 As described above, according to the present embodiment, by adopting a configuration in which a water capillary portion which is continuous from the surface of the drain portion and which is stored in the water channel of the water storage portion is provided in the drain portion of the water storage portion The phenomenon is that the phenomenon is not continuously dripped into the water receiving portion by the passage 7 and is provided in a refrigerator having a water storage portion and a drain pipe (water receiving portion) that discharges water from the water storage portion (four). Let the water drip from the Ministry of Finance to the drain pipe (water receiving department). The above is only the preferred embodiment of the present invention, and is not intended to limit the scope of the present invention. The preferred embodiments of the present invention are as described above. The skilled person 'can make a slight change or modify the equivalent of the equivalent change when the structure and technical content of the above-mentioned disclosure can be used without departing from the technical scope of the present invention. Any simple modification, equivalent change and modification of the above embodiments in accordance with the technical essence of the present invention are still within the scope of the technical solution of the present invention.  Although the present invention has been disclosed in the above preferred embodiments, it is not intended to limit the invention to any skilled person, and in the scope of the invention of the invention, it is possible to make some changes and retouching, and thus the present invention The scope of the second application is subject to the definition of the scope of the patent application. [Simple description of the diagram] Figure 1 shows the first! A schematic cross-sectional side view of the entire refrigerator of the embodiment. Fig. 2 is a front view of the refrigerator main body in a state in which a door or a panel is removed. Fig. 3 is a schematic perspective view of the vicinity of a micro-freezing chamber. 49 201205019 Figure 4 is an enlarged front view of the shoulder of the special duct for fog. Figure 5 is a cross-sectional plan view taken along line X and XI of Figure 4 . Fig. 6 is a longitudinal sectional side view taken along line Χ2*·Χ2 in Fig. 4; Fig. 7 is a longitudinal sectional side view taken along line X3-X3 of Fig. 4; Fig. 8 is a longitudinal sectional side view taken along line Χ4-χ4 of Fig. 4; Fig. 9 is a vertical cross-sectional front view of the lower portion (microbeam chamber) of the refrigerating compartment and the vicinity of the vegetable compartment. Fig. 10 is a longitudinal sectional side view taken along line Χ5_Χ5 of Fig. 9. Figure 11 is a longitudinal sectional front view of the electrostatically atomizing device portion. Fig. 12 is a plan view showing a refrigerating cooler, a water storage container, and a drain pipe portion. Figure 13 is a vertical view of the drain pipe. Fig. 14 is an enlarged longitudinal sectional side view taken along line Χ6·Χ6 of Fig. 13; Figure 15 is a body diagram of a water storage container. Fig. 16 is a longitudinal sectional side view taken along line Χ7_Χ7 of Fig. 15. Fig. 17 is a longitudinal sectional side view taken along line Χ8_Χ8 of Fig. 15. 18(a) and 18(b) are views showing a water passage forming member, Fig. 18(a) is a front view, and Fig. 18(b) is a right side view. Fig. 19 is a longitudinal sectional side view showing a main part of a second embodiment. Fig. 20 is a longitudinal sectional front view of a main part of a third embodiment. Fig. 21 is a longitudinal sectional side view of the main part. Fig. 22 is a view corresponding to Fig. 20 of the fourth embodiment. Fig. 23 is a view corresponding to Fig. 19 of the fifth embodiment. Fig. 24 is a front elevational view schematically showing the cooler of the sixth embodiment and its peripheral portion 50 201205019. Fig. 25 is a perspective view showing a cooler and a peripheral portion thereof according to a sixth embodiment. Fig. 26 is a view corresponding to Fig. 8 of the seventh embodiment. Fig. 27 is a perspective view showing a cooler and a peripheral portion thereof according to the eighth embodiment. Fig. 28 is a view corresponding to Fig. 8 of the ninth embodiment. Fig. 29 is a view corresponding to Fig. 11 of the tenth embodiment. Fig. 30 is a view corresponding to Fig. 15 of the eleventh embodiment. Figure 31 is an enlarged longitudinal sectional side view taken along line X9-X9 of Figure 30. [Description of main component symbols] 1 : Refrigerator body 2 : Insulation box 2a : Outer box 2b : Inner box 2c, 38 . Insulation material 3: refrigerator compartments 3a, 4a, 5a, 7a: heat insulation door 4: vegetable compartment 5: ice making compartment 6: small freezer compartment 7: freezer compartment 8: automatic ice making apparatus 8a: ice making box 51 201205019 ίο : Partition wall 11: Lower case 12: Upper case 13: Shelf 14: Micro-freezer 15: Egg box 16: Small box 17: Water tank 18: Micro-frozen box 18a: Front surface wall 18b: Notched portion 19: Thermal insulation Partition wall 20: ice storage container 22: storage container 24: refrigerating cooler (cooler) 24a: coolant tube 24b: heat-conducting fin 24c: end portion 24d: right end portion (storage of a portion in contact with the tube in the cooler) End portion on the water side) 25: Cooling cooler 26: Machine room 27: Compressor 28: Defrost water evaporation m 52 201205019 29: Control device 30: Cooler chamber 30a: Cooling air outlet 30b: Return port 31: Refrigeration blower fan 32: drain pipe 34: cold air duct 35: refrigerating blower fan 36: refrigerating cooler chamber 36a: front wall 36b: section 36c: lower section 37: cold air supply duct 39: cold air supply port 40: drainage Tube (tube) 40a: bottom wall 40b: rear wall portion 40c: side wall portion 40d: front wall portion 40e, 113c: protruding portion 40f: support portion 40 g, 105a: front surface 41, 97: drain port 42: air supply duct 53 201205019 43 : suction port 45: special duct for mist 46: duct constituent members 48, 110: electrostatic atomization devices 50, 112: mist discharge portion 51, 111: mist generating unit 52: power supply device (transformer) 53: water supply portion 53a: horizontal portion 53b, 113b: vertical portion 53c: curved portion 54, 114: cartridges 55, 115: water retaining material 56, 191: water storage container (storage 56A: bottom wall portion 56b: front wall portion 56c: left side wall portion 56d: right side wall portion 57: mist release pin 58: power receiving pin 60: wire 61: power supply terminal 62: cold air supply port 63: facing The mist duct 54 of the refrigerator compartment 201205019 63a: the mist outlet of the refrigerator compartment 65: the mist outlet of the micro-freezer 66: the mist outlet of the egg box 67: the mist outlet of the vegetable compartment 68: the cold air supply port of the micro-freezer 69: the coolant Tube 70: mounting plates 71a, 71b: partitioning plate 72: fresh-keeping cover 73: air passages 74a, 74b, 77: vent 75: communication port 76: V-ducts 80, 95, 96, 102, 103, 106: separated Department 80a. Right end portion 80b: Left end portion 80c: Right portion 80d: Side surface 81: Mounting portion 82: Lowest portion 83: Left rear wall 83a, 84a, 86, 88 • Projection 84: Right rear wall 85, 195: Drainage portion 55 201205019 87, 91, 196: water passage 90: water passage forming member 92: elastic engagement claw 93: projection 95a: surface 95b: rear surface 100: first drainage port 101: second drainage port 105: concave portion 113a: circular portion 156a : overflowing portion 171 : water collecting ring (water collecting portion) 181 , 200 : water collecting plate (water collecting portion) 181 a : C ring portion 181 b · inclined portion 192 : supporting frame portion 193 : water collecting pipe portion 193 a : water receiving groove Portion 193b: dripping groove portion 200a: connecting portion 201a, 201b: water collecting plate A A2, B1, B2, B3, Cl, C2: arrow 56

Claims (1)

201205019 VII. Patent application scope: 1. A refrigerator characterized by comprising: a cooler; a water portion storing water to which an applied voltage is applied to the atomizing device; and & 'in contact with the cooler And a defrosting water generated by the defrosting of the cooler, and a partition portion is provided in the tube that receives the defrosting water, and the partition portion is partitioned to avoid the water storage portion The water is connected to the defrosting water from the said. 2. The refrigerator according to claim 1, wherein the partition is provided on an upper surface of the bottom of the tube. 3. The refrigerator according to claim 2, wherein the water storage unit has a drain portion that discharges water stored in the water storage portion, and a partition portion provided in the tube is disposed in the cooling The device contacts the end of the portion of the tube on the water reservoir side and the drain portion. 4. The refrigerator according to claim 3, wherein the pipe is provided with a drain port, and the partition portion extends to the drain port. 5. The refrigerator according to claim 1, wherein the partition portion is inclined. 6. The refrigerator according to claim 1, wherein the partition is provided below the cooler and in the tube on a wall in contact with the cooler. The refrigerator according to claim 6, wherein the tube has a drain port, and the second direction is to receive the defrosted water from the cooler and guides 8. As disclosed in claim 1 The refrigerator, wherein the tube has a first drain port for defrosting water from the cooler, and has water located below the water portion of the jugbeth and dripping from the water storage portion The second drain that is discharged. 9. The refrigerator according to claim 1, wherein the cooling H is configured such that the cold tube passes through a plurality of heat transfer fins in a meandering direction in the vertical direction, and a plurality of rows are arranged side by side in the front-rear direction. The water storage portion is disposed below the cooler and at a position facing the coolant pipe of the first row on the front side of the coolant pipe. 10. The refrigerator according to claim 9, wherein the water storage portion is disposed apart from the cooler. 11. The refrigerator according to claim 2, further comprising: a power supply device that applies a voltage to the mist releasing portion that emits the mist, wherein the mist discharging portion is disposed above the water storage portion, in the cooler An insulator is disposed between the mist discharge portion. 12. The refrigerator according to claim 4, wherein a water collecting portion that collects the defrosting water is provided in the coolant pipe, and the water storage portion is spaced apart from the water collecting portion. Configuration. The refrigerator according to claim 1, wherein the water storage portion is provided with a drain 58 201205019 for discharging the stored water, and is provided from the surface of the drain portion to the back surface. The water passage is configured such that water stored in the water storage portion is continuously dripped into the tube through the water passage by capillary action. 14. The refrigerator according to claim 13, wherein the water passage is present on both sides in a width direction of the drain portion. 15. The refrigerator according to claim 14, wherein the water passage is formed by adjacent convex portions. 16. The refrigerator according to claim n, wherein the water passage is formed by attaching a U-shaped water passage forming member to an end portion of the drain portion. 17. The refrigerator according to claim 14, wherein the water passage is formed by a groove. 59