TW201042224A - Electric refrigerator - Google Patents

Abstract

The issue of this invention is to generate and supply mist having sterilizing effect to a storage chamber without generating harmful gas such as ozone although an electrostatic atomizing device is taken as a mist generation means. The solution of this invention is that an electrostatic atomizing device is installed (36) on a partition board (8) defined between a refrigeration chamber (3) and a vegetable chamber (4). Water (W) in a water storing tank (43) is supplied to a mist releasing portion (49) by passing through a water absorbing pin (48), a water retention material (47) and an electric conductive membrane (46). Negative high voltage of a DC high-voltage power device (56) is imposed to the mist releasing portion (49), through electric discharging generated from the mist releasing portion (49), to release the mist containing hydroxyl free radical that has strong oxidation. The mist is supplied to the vegetable chamber (4) from a mist releasing outlet (52).

Description

201042224 VI. Description of the invention:  [Technical Field of the Invention] The present invention relates to a refrigerator in which a mist generated in an electrostatic atomization device is supplied to a storage chamber.  [Prior Art] In the past, there was a fruit and vegetable room in which a mist generating device (an ultrasonic atomizing device or an electrostatic atomizing device) was installed in a storage room. By supplying the mist generated from the mist generating device to the vegetable and fruit room, The composition for maintaining the freshness of the fruits and vegetables (see, for example, Patent Document 1). In addition, it is considered that such a mist generating device is used for the removal of harmful substances such as pesticides attached to fruits and vegetables (for example, see Patent Document 2). Or it is used for sterilization or deodorization (for example, refer to Patent Document 3).  [PRIOR ART DOCUMENT] [Patent Document 1] [Patent Document 1] Japanese Patent No. 4179398 [Patent Document 2] JP-A-2008-116198 (Patent Document 3) JP-A-2003-79714 】 [To solve the problem of the invention] However, the use of a super-chopper type atomizing device as a mist generating device has a large particle size of mist. The dirt contained in the stored water of the mist generating device 201042224 The scale component also becomes a mist. There is also the concern that such mist is supplied to the storage room.  on the other hand, Using an electrostatic atomizing device, The particle size of the mist can be made fine (e.g., a few n m to several tens of n m). however, The electrostatic atomization device disclosed in Patent Document 1, The atomizing electrode (the mist releasing portion) for generating the mist and the counter electrode (the counter electrode) are arranged in close proximity to each other.  therefore, Corona discharge is generated between the atomizing electrode and the counter electrode, And ozone is easily generated along with the corona discharge. Gases with high ozone concentrations are harmful to humans. The user is exposed to harmful gases.  The present invention has been made in view of the above circumstances, Its purpose is to provide one, Even if an electrostatic atomization device is used as a means for generating mist, Nor will harmful gases such as ozone be produced. It can generate a mist containing a hydroxyl radical of the sterilizing action. And supply it to the storage room, A clean and safe refrigerator.  [Means for Solving the Problem] In order to achieve the above objectives, The refrigerator constructed by the present invention, It is a refrigerator with a storage compartment in a refrigerated temperature zone. Its characteristics are: With electrostatic atomization device, The electrostatic atomizing device has: Fog release section; Supplying water to the water supply portion of the mist release portion; And applying a negative high voltage to the aforementioned mist release portion, a structure of a DC high-voltage power source device for releasing mist from the mist release portion, On the other hand, a structure is provided in which the mist released from the mist releasing portion is supplied to the storage chamber.  201042224 [Effects of the Invention] According to the refrigerator of the present invention, It can suppress the generation of harmful gases such as ozone, And give full play to the effect of fog.  [Embodiment] [Formation for Carrying Out the Invention] (First Embodiment) 〇 Hereinafter, Referring to Figures 1 to 7, The first embodiment of the present invention will be described. First of all, In Figure 1, The heat insulating box 2 of the refrigerator body 1 is formed by filling a foamed heat insulating material between the outer box and the inner box. Inside the refrigerator body 1, From above: Cold storage room 3, Fruit and vegetable room 4, And the ice making room 5 and the small freezing room (not shown) are arranged to the left and right. A freezer compartment 7 is provided at the lowermost portion.  Among them, Refrigerator 3 and fruit and vegetable room 4, The temperature inside the library is controlled at a refrigerating temperature of 1 to 4 °C. They all constitute a storage compartment in the refrigerated temperature zone.  Ο Since the refrigerating compartment 3 and the fruit and vegetable compartment 4 are storage compartments in the same refrigerating temperature zone, Therefore, it is basically divided into upper and lower sides by the partition plate 8 formed of synthetic resin.  Other ice storage rooms in the storage room 5 The small freezer compartment and the freezer compartment 7 are storage compartments that constitute a freezing temperature zone. In addition, The small freezer compartment can also be used as a temperature switching chamber that can switch the set temperature according to the user. The vegetable and fruit room in the lower part of the refrigerated temperature zone Between the ice making chamber 5 and the small freezing chamber located in the freezing temperature zone directly below the vegetable and fruit chamber 4, It is distinguished by the partition 9 of the heat insulating zone.  The refrigerating compartment 3 is opened and closed by a side-opening rotatable possible door 3a 201042224, And other fruits and vegetables room 4, Ice making room 5, Small freezer and freezer 7,  Is to become a drawer type door 4a, 5a, 7a to open and close.  In addition, In each storage room (refrigerator 3, Fruit and vegetable room 4, Ice making room 5 Small freezer, The freezing chamber 7) is provided with a corresponding door 3a, 4 a, 5 a , 7 a open and close door switch (not shown). An automatic ice making device 1 2 (ice making device) equipped with an ice tray 1 is disposed in the ice making chamber 5.  A refrigerating cooler 13' is disposed on the back of the lower portion of the refrigerating compartment 3, and cold air cooled by the refrigerating cooler 13 is disposed on the back of the vegetable compartment 4. It is supplied to the refrigerating compartment 3 and the vegetable and fruit compartment 4 of the storage compartment of the refrigerating temperature zone, And the refrigeration fan 14 is circulated.  A cold air passage 15 is provided behind the refrigerating compartment 3. The cold air passage 15 is provided with a plurality of cold air outlets 15a, The cold air in the cold air passage 15 is blown out from the cold air outlet 15a into the refrigerating compartment 3.  also, A refrigerating cooler 16 is installed on the back of the freezing compartment 7 and a cool air cooled by the freezing cooler 16 is disposed on the back of the freezing compartment 5 and the small freezing compartment. Ice making room supplied to the storage compartment of the freezing temperature zone 5  Small freezer and freezer 7, And the refrigeration fan 17 is circulated.  At the rear bottom of the refrigerator body 1, a compressor 19 in which a mechanical chamber 18 is disposed is provided with a refrigeration cycle. This compressor 19 is shared by the refrigerating cooler 13 and the refrigerating cooler 16.  In the lower part of the refrigerating compartment 3, As shown in Figure 2, the position is above the partition plate 8, The ice-making water supply tank 20 is detachably attached to the left end. In the right side of the ice-making water supply tank 2, the drawer type glove box 2 1 and the egg box 22 are set up and down. A freezer compartment 23 is provided on the right side.  -8 - 201042224 A freezer box 24 is provided in the freezer compartment 23. At this time, 'Ice for the sink 2 Ο, Miscellaneous box 21, Egg box 22, The front end of the freezing compartment 23 is located rearward than the front end of the partition plate 8, and a space portion is formed above the front portion 8a of the partition plate 8. This space portion is a space for the door pocket 25 (see Fig. 1) provided on the inner surface of the door 3a of the refrigerating compartment 3.  A water receiving container 28 is provided at the rear of the water supply water supply tank 2' as shown in Fig. 3'. Between the water supply water supply tank 20 and the water receiving container 0 28, a water supply mechanism 29 for supplying water for the ice making water supply tank 2 to the water receiving container 28 side is provided.  This water supply mechanism 29 becomes the next structure. As shown in Fig. 4, a pump motor 30 is provided below the water receiving container 28, and a pump 31 is provided in the above-described ice making water supply tank 20, Formed by the pump motor 30, The configuration of the pump 31 is driven in a non-contact manner.  Although not shown in detail, But simply explain its driving principle. A permanent Q magnet 3 2 that is rotationally driven by the pump motor 30 is provided at a front end portion of the pump motor 30. With the rotation of its permanent magnet 3 2 , The ice making is rotated by the pumping vane of the pump 3 1 in the water tank 20 Pump action.  When pumping, Use ice making to the water in the water tank 20,  It is supplied to the water receiving container 28 via the water supply pipe 3 3 . The water supplied to the water receiving container 28 is formed via the water supply pipe 34, The structure of the ice tray 1 1 supplied to the above-described automatic ice making device 1 2 .  then, An electrostatic atomizing device 36 is disposed at a front portion 8a of the partition plate 8 between the compartment refrigerating chamber 3 and the vegetable and fruit chamber 4, the following, The configuration of the electrostatic atomizing device 36 will be described with reference to Figs. 6 and 7'.  -9 - 201042224 Electrostatic atomizing device 3 6 is shown in Figure 2 and Figure 3, In the front portion 8a of the partition plate 8, It is arranged in the approximate center part of the left-right direction. Under the partition plate 8, A bottom plate 37 for mounting the electrostatic atomizing device 36 is mounted, In the partition plate 8, an opening portion 39 for taking out the atomizing unit 38 of the electrostatic atomizing device 36 is formed.  In the zone partition 8, The cover 40 that opens and closes the opening portion 39 is provided to be slidable in the front-rear direction. A unit accommodating portion 41 for accommodating the atomizing unit 38 is provided between the partition plate 8 and the bottom plate 37.  The atomizing unit 38 has: a water storage tank 43 for storing water W (corresponding to a water storage portion); An upper box 44 assembled in an upper portion of the water storage tank 43; And a unit cover 45 that covers the upper case 44 from above. In the upper box 44 is provided: Conductive sheet 46, Water retention material 47, Water absorption pin 48, A plurality of mist release portions 49.  Among them, The conductive sheet 46 is, for example, a mixed polyester fiber and a carbon fiber as a conductive material. And forming a felt (non-woven), And have water retention, Moisture absorption characteristics, And the conductivity ' is disposed in the upper portion of the upper case 44.  The water retaining material 47 is, for example, made of urethane &  The "sponge structure" is excellent in water retention property and moisture absorption characteristics. The upper surface is disposed in contact with the lower surface of the conductive sheet 46. The water retaining material 47 is thicker than the conductive sheet 46.  The water absorbing pin 48 is, for example, a product in which the polyester fiber is inspected to form a pin shape, and the water absorbing property and water absorbing property are excellent. The water absorbing pin 48 is in contact with the conductive sheet 46 through the above-mentioned water retaining material 47 at the upper end portion. Further, the lower end of the water absorbing pin 48 - 201042224, the end portion is formed by the tubular portion 44 a passing through the upper case 4 4, The state of being inserted into the water W in the water storage tank 4 3 .  The mist release unit 49 is the present embodiment. For example, a mixed polyester fiber and a carbon fiber as a conductive material are twisted to form a pin shape. And the pin-shaped release member is configured by a plurality of pieces arranged side by side. It has the same water retention and moisture absorption characteristics as the water absorbing pin 48. Further, it has electrical conductivity similarly to the conductive sheet 46. The front end of the mist release portion 49 is formed to be more and more thin at the tip end. A curved surface shape with a moderate circle.  A Colloidal platinum was attached to the mist release portion 49. The nano platinum fine particle colloid is, for example, immersed in the mist release portion 49 to the treatment liquid containing the colloid of the nano platinum fine particles and can be attached by calcination. The upper end portions of the respective mist releasing portions 49' are in contact with the conductive sheet 46.  also, The lower end portion of the mist release portion 49 protrudes in a state of hanging down from the lower portion of the upper case 44 through the upper case 44'. The upper cover 44 release cover cover 50 is detachably provided to cover the mist release portion 49.  A release port 5 1 positioned below the mist release portion 49 is formed in the release portion cover 50. A mist discharge port 52 located behind the discharge port 5 1 is formed in the bottom plate 37.  The mist release port 52 communicates with the upper portion of the vegetable and fruit chamber 4. When the release port 51 is in communication with the mist release port 52, when the mist is released from the mist release portion 49, The mist is supplied from the discharge port 51 through the mist discharge port 52 into the vegetable compartment 4 as shown by the arrow A in Fig. 6.  herein, The water absorbing pin 48 picks up the water W' in the water storage tank 4 3 and supplies it to the water material 47 and the conductive sheet 46. The water retaining material 47 is kept from the supplied water. Further, the water is supplied to the conductive sheet. The conductive sheet 46 is supplied from the water absorbing pin 48 and the water retaining material to the mist releasing portion 49. at this time, Water absorption pin 48,  , The conductive sheet 46 is configured to supply moisture to the mist releasing portion 49. When the atomizing unit 38 is installed in the unit housing portion 41,  The state in which the cover 40 is opened is as shown in Fig. 6 after the arrow B1 is inserted from the opening portion 39 into the unit housing portion 41. By way of action, Installed to a regular installation location.  also, When the atomizing unit 38 is taken out from the unit accommodating portion 41, 6 is indicated by an arrow B2. After sliding to the front,  The unit 38 is taken out from the opening portion 39.  In the atomization unit 3 8 ' as shown in Figure 7, It is set in such a way that the power supply pin 5 4 protrudes. The feed pin 54 is connected to the conductive sheet 46 via a base end portion.  The timing at which the atomizing unit 38 is installed in the unit housing portion 41 is The front end portion of the power supply pin 54 is inserted and connected to the chassis 58. The connector 58 is connected to the DC high voltage power supply terminal 57.  herein, Forming the aforementioned mist release portion 49 via conduction, Power supply pin 5 4, Connector 5 8, Apply a DC high voltage power supply 丨 negative high voltage (_ 4~-1 Ok V ). (From the Japanese public license 0 water-absorbing pin 4 8 46 ° 4 7 supplied to the water-maintaining material 4 7 - the water supply unit is the front: The way,  : Slide back, As shown in the figure, lift the atomization toward the rear. Electrical components 5 5 : The position of the gauge 3 7 side of the negative sheet of I 5 6 46 the spoon of the device 5 6 0026, 27 -12- 201042224 When a negative high voltage of the DC high-voltage power supply unit 56 is applied to each of the mist discharge units 49, the current concentrates on the front end portion of the mist discharge unit 149 which is most easily discharged.  With this, A natural discharge phenomenon occurs in each of the mist release portions 49, Utilizing the ion wind generated by the discharge, The water split on the surface of the mist release portion 49 is released into a fine mist.  in this way, The electrostatic atomizing device 36 does not have a counter electrode with respect to the mist releasing dam portion 49. therefore, Since ozone does not occur, Therefore, the released mist does not contain ozone.  A positioning convex portion 60 for positioning the atomizing unit 38 is provided at a bottom portion of the unit housing portion 41, Further, a unit detecting switch 61 for detecting the mounting state of the atomizing unit 38 is provided. also, A cover switch 62 and a handle 63 are provided at the front of the bottom plate 37.  When the cover 40 is rotated, the handle 63 is rotated by the pressing portion 6 4 of the cover 4 , When the lid switch 62' is pressed to open the lid 40, Ο The opening and closing of the cover 40 is detected by the lid switch 62 by releasing the pressing operation of the lid switch 62.  In the water storage tank 43, as shown in Fig. 7, a filter filter 65 is formed in a container shape. Further, an ion exchange resin 66 is accommodated in the filter filter 65. The unit cover 45 is provided with a cylindrical water injection port 6.7 extending downward from the filter filter 65'.  The water injection cover 68 that opens and closes the water inlet 67 at the unit cover 45 is detachably mounted. When the water filling cover 68 is removed, Water can be supplied from the water inlet 67 to the water tank 43.  Further, the photocatalyst 69 ° made of, for example, titanium oxide is applied to the inner surface of the water storage tank 43. A light source (for example, an ultraviolet LED) 70 that emits ultraviolet light is provided at the bottom of the unit housing portion 4 1 . When this light source 7 illuminates, The ultraviolet ray "photocatalyst ό 9 is irradiated to the water storage tank 43 to receive the ultraviolet ray and is activated.  And play a sterilization role.  In the aforementioned vegetable and fruit room 4, as shown in Figure 1, Featuring: Lower container 72, And an upper container 73 disposed at an upper portion of the lower container 72. The upper container 73 is lower than the lower container 72, The length in the front and rear direction is formed smaller, And it is disposed on the rear side of the lower container 72.  The front end portion of the upper container 73 is positioned below the mist discharge port 52 of the bottom plate 37. and, In this state, When the mist is released from the mist release port 52 into the fruit and vegetable compartment 4, The mist is supplied to both the lower container 72 and the upper container 73 (see Fig. 6).  A control unit 75 containing a microcomputer is provided at the back of the refrigerator body 1 (see Fig. 1). The control device 75 is configured to have a compressor 19 or a refrigerating fan 14 that is controlled to be a refrigeration cycle, Refrigeration fan 17, Automatic ice making device 1 2 The pump motor 3 of the water supply mechanism 29, Electrostatic atomizing device 3 6 'The body of the refrigerator such as the light source 70! The overall control of the function of the action.  The control device 75, in particular, constitutes the electrostatic atomizing device 36. Only the door switches of the respective storage compartments detect the locking of the door. And the aforementioned cover switch 6 2 of the electrostatic atomizing device 36 detects the latching of the cover 40, Further, in a state where the unit detecting switch 6 1 detects the mounting state of the atomizing unit 38, The energization of the electrostatically atomizing device 36 is allowed.  -14- 201042224 Therefore, Once it is detected that the door of any storage room is opened,  Or when the lid 4 is opened, When the atomizing unit 38 is not installed, the energization of the electrostatic atomizing device 36 is turned off. also, The control device 75 causes the light source 70 to perform lighting control for a predetermined period of time every predetermined time.  Explain the role of the above construction.  The atomizing unit 38 is installed in the unit housing portion 41, Closing the cover 40 of the unit housing portion 41, And in the state where the doors of each storage compartment are locked, When driving the electrostatic atomizing device 3 6 A fine mist is released from each of the mist release portions 49, The mist is supplied from the mist discharge port 52 to the upper container 73 and the lower container 72 of the vegetable compartment 4.  The mist contains a hydroxyl radical with strong oxidation. The mist containing the hydroxyl radicals thereof is supplied to the upper container 73 and the lower container 72 of the vegetable and fruit chamber 4, This sterilization or deodorization is made possible.  also, With its fog, The freshness of the fruits and vegetables accommodated in the upper container 73 and the lower container 72 can be expected. and, By causing the light source 70 to perform lighting control for a certain period of time at each predetermined time, The photocatalyst 69 in the water storage tank 43 is activated. The sterilization action in the water storage tank 4 3 can be expected.  however, Because the electrostatic atomizing device 36 has no water, Can't produce fog, Therefore, water must be replenished regularly. also, When it is attached to the surface of the mist release portion 49 by the adhesion of the occurrence of the mucus, Because the release of mist is degraded, So for example, once a year, It is preferable to perform the cleaning of the mist release portion 49.  -15- 201042224 In this case, After opening the door 3a of the refrigerating compartment 3, the cover 40 of the front portion 8a of the partition plate 8 is slid, The opening portion 39 of the unit housing portion 41 is opened. then, The user inserts the hand into the unit housing portion 41, After the atomizing unit 38 of the electrostatic atomizing device 36 is slid forward, It is picked up and taken out from the unit housing portion 41. at this time, The connection of the connector 58 to the power supply pin 54 is detached.  If only water is supplied, In the state where the water injection cover 6 8 is removed,  Replenish water from the water inlet 67. also, When the mist release portion 49 is also cleaned, While the upper case 44 is being detached from the water storage tank 43, The release cover 50 is removed from the upper case 44, The cleaning is performed in a state where the mist release portion 49 is exposed 〇 In addition, When only water is supplied, The atomizing unit 38 can be attached to the unit housing portion 41 by simply removing the water filling cover 68.  In addition, After the water supply or cleaning, After the atomizing unit 38 is mounted in its original state, the atomizing unit 38 is housed in the unit housing portion 41, And installed to a regular location. at this time, The power supply pin 54 is inserted and connected to the connector 58. After that, the cover 40 is slid forward to close the opening portion 39. The door 3a of the refrigerating compartment 3 is closed.  According to the first embodiment described above, The following effects can be obtained 〇 The partition plate 8 between the refrigerating compartment 3 and the vegetable compartment 4 is provided with an electrostatic atomizing device 36 having a structure that does not generate ozone, The mist released from the mist releasing portion 49 of the electrostatic atomizing device 36 is mainly supplied to the structure of the vegetable-fruit-16-201042224 chamber 4. According to this, a method of supplying a mist containing a hydroxyl radical having a strong oxidizing action into the fruit and vegetable compartment 4, It is possible to sterilize or deodorize the inside of the vegetable and fruit compartment 4. also, With its fog, The freshness of fruits and vegetables, etc. can also be expected.  Electrostatic atomizing device 3 6, Since the counter electrode of the mist release portion 49 is not provided, So with the mist release and the opposite pole, The previous constructs of corona discharge are different. It can suppress the generation of harmful gases such as ozone. It can improve safety.  The electrostatic atomizing device 36 has a water storage tank 43 for storing water W, And constituted by the water absorbing pin 48, Water retaining material 47 and conductive sheet 46, The water W stored in the water storage tank 43 is supplied to each of the mist discharge portions 49. With this, Since the water can be stably supplied to the mist release portion 49, Therefore, the amount of mist generated from the mist releasing portion 49 can be stabilized.  also, Storage tank 43, Since the unit containing the atomizing unit 38 can be attached to and detached from the unit housing portion 41, Therefore, the supply of water to the water storage tank 43 can be easily performed. Since the mist release portion 49 can also be loaded and unloaded together with the water storage tank 4 3 , Therefore, the cleaning of the mist release portion 49 can be easily performed.  Since the filter filter 65 is provided in the water storage tank 43, Therefore, the water that is replenished into the water storage tank 4 3 can be purified. The cleaned water can be supplied to the mist discharge portion 49. With this, It is possible to prevent the occurrence of a blockage such as the mist release portion 49 as much as possible. It can prevent the amount of mist emission from decreasing.  also, Since the ion exchange resin 6 6 is housed in the filter filter 65, Therefore, the mineral component contained in the water W stored in the water storage tank 43 can be adsorbed on the ion exchange resin 66 thereof. And remove it.  -17- 201042224 By this, It is possible to prevent the rust from accumulating in the mist release portion 49 and the like as much as possible. And can prevent the occurrence of blockages, Further, the reduction in the amount of mist released can be further prevented. By the way, The service life of the mist release portion 49 can be made longer 〇 In addition, By every predetermined time, The way in which the light source 70 is illuminated for a certain period of time, The photocatalyst 69 in the water storage tank 43 is activated, The sterilization action in the water storage tank 43 can be expected. Even with this method, The cleaned water can also be supplied to the mist release portion 49.  Since the atomizing unit 38 of the electrostatically atomizing device 36 is disposed at the front portion 8a of the partitioning plate 8, Therefore, the replenishment of the water of the atomizing unit 38 or the loading and unloading of the atomizing unit 38 can be easily performed. Since it constitutes the mist released from the mist releasing portion 49 of the atomizing unit 38, The upper container 73 and the lower container 72 of the vegetable and fruit chamber 4 are supplied from above, Therefore, mist can be supplied to both the upper container 73 and the lower container 72.  a method of attaching the nano platinum microparticle colloid to the mist release portion 49,  The mist released from the mist releasing portion 49 easily generates hydroxyl radicals', and the sterilization function or the deodorizing function can be further enhanced. also, The conductivity of the mist releasing portion 49 can be favorably maintained by including the conductive material (carbon) in the mist releasing portion 49.  Because it is made into a storage room (refrigerator 3's fruit and vegetable room 4' ice making room 5, Small freezer, Door 3 of the freezer compartment 7), 4 a, 5 a, 6 a, When any one of 7 a is opened, Disrupting the energization structure of the electrostatic atomizing device 36, Therefore, it is possible to prevent the user from coming into contact with the high voltage portion. Security can be improved. At this time, at least when the door 3a of the refrigerating compartment 3 is opened by -18-201042224, It suffices to block the energization of the electrostatic atomizing device 36.  also, In the present embodiment, the lid switch 62 that is configured to open and close the lid 4 of the unit housing portion 41 in which the atomizing device 36 is stored is provided. When the cover 40 is opened, the energization of the electrostatically atomizing device 36 can also be interrupted. So you can improve your security.  Furthermore, Since the unit detecting switch 61 is provided in the unit housing portion 41, Therefore, when the atomizing unit 38 is not installed, the electrostatic atomizing device 36 does not have a power-on condition. And can further improve security.  (Second embodiment) Next, A second embodiment of the present invention will be described with reference to Fig. 8'. The same portions as those in the first embodiment are denoted by the same reference numerals and the different portions will be described. Fig. 8 is a longitudinal front view of a portion of the atomizing unit 78 in which the electrostatic atomizing device 7 is disposed as seen from the front side.  In Figure 8, The unit housing portion 79 accommodating the atomizing unit 78 is provided integrally with the partition plate 8. The position of the unit housing portion 79 is located at almost the same position as the unit housing portion 41 of the first embodiment. The atomizing unit 78 is detachably provided in the unit housing portion 79.  The upper opening portion 80' of the unit housing portion 79 is opened and closed by a cover 8 1 which is slidable in the front-rear direction. A lid switch 82 that detects opening and closing of the lid 8 1 is provided in the upper opening portion 8A.  The unit case 84' of the atomizing unit 78 is in the form of a rectangular container forming an opening. There is a water storage tank 8 5 (corresponding to the water storage part). Water W for atomization is stored in the water storage tank 85. In the water storage tank 85, Container-shaped over -19- 201042224 Filter filter 8 6 is detachably received, An ion exchange resin 87 is accommodated in the filter filter 86.  Above the unit box 84, The unit cover 88 is detachably attached so as to cover the water storage tank 85 from above. The water injection cap 90 that opens and closes the water injection port 8 9 at the unit cover 8 8 ' is detachably attached to the upper position of the filter filter 86.  herein, When the water is supplied to the water storage tank 8 5, the water is supplied from the water injection port 8 9 to the filtration filter 86 in a state where the water injection cover 90 is removed. at this time, Water W to be replenished, It is filtered through the filter through the filter 86. also, In the filter filter 86, due to the containment of ion exchange resin 87 Therefore, the mineral component contained in the water W is formed by being adsorbed on the ion exchange resin 87.  therefore, The water W' contained in the water storage tank 85 is purified in the water storage tank 85. The water W to be purified is supplied to the right side of the unit case 84, which is supplied to the water absorbing pin 91° which will be described later. The pin holding case 92 is detachably mounted. The pin holding case 92 is provided with: Water absorption pin 91; Conductive sheet 93; Water retaining material 94; Forming a plurality of pin-shaped mist release portions 95; And the power supply pin 96.  herein, Water absorption pin 91, Conductive sheet 93 'water retaining material 94, Fog release part 9 5, The water absorbing pin 48 of the first embodiment is respectively Conductive sheet 4 6 'water retaining material 4 7 , The mist release portion 4.9 is formed of the same material. The conductive sheet 93 is disposed at the uppermost portion of the pin holding case 92. Bao -20- 201042224 The water material 94 is disposed in a state where the upper surface is in contact with the lower surface of the conductive sheet 913. The water retaining material 94 is thicker than the conductive sheet 93. Each mist release portion 95, The respective upper end portions are in contact with the conductive sheet 93 through the water retaining material 94.  also, The lower end portion of each of the mist release portions 95 is a through pin holding case 92. The state is suspended toward the inside of the unit case 84. At the bottom wall portion of the unit case 84, a discharge port 7-1 which is formed by a plurality of holes 〇 under the mist discharge portion 95 is formed.  Water absorbing pin 91, The upper end portion is in contact with the water retaining material 94, and the lower end portion penetrates the pin holding case 92. It is in a state of being inserted into the water W in the water storage tank 85.  herein, The water absorbing pin 9 1 sucks the water in the water storage tank 8 5 to the water retaining material 94. Water retention material 9 4, Is to keep the water supplied from the water absorbing pin 91, Further, water is supplied to the conductive sheet 93 and each mist releasing portion 95. at this time , a water absorbing pin 91 and a water retaining material 94 and a conductive sheet 93, It is a water supply unit that supplies water to the mist release unit 975.  The upper end portion of the power supply pin 96 is in contact with the conductive sheet 93 through the water retaining material 94. The lower end portion of the power supply pin 96 is protruded downward through the pin holding case 92, The front end protrudes rearward.  therefore, The power supply pin 96 is viewed from the side in an L shape. After the atomizing unit 78 is housed in the unit housing portion 79, By sliding to the rear, Forming the rear end portion is inserted into the connector 98. The negative electrode of the DC high voltage power supply unit 56 (see Fig. 6) is connected to the connector 98.  At this time, when the negative high voltage of the DC high voltage power supply unit 56 is applied -21 - 201042224 at the power supply pin 96, The negative high voltage is also applied to each of the mist release portions 95 via the conductive sheets 93 and moisture. This result, A natural discharge phenomenon occurs in each mist discharge portion 95. The moisture on the surface of the mist releasing portion 95 is split to form a fine mist which is released.  The electrostatic atomizing device 7 does not have a counter electrode with respect to the mist releasing portion 95 to which a negative high voltage is applied.  A mist release port 99 located below the discharge port 97 is formed in a bottom wall portion of the unit housing portion 79, The mist is released from each of the mist release portions 95, Become through its mist release port 99, It is supplied to the vegetable and fruit room 4 below.  The mist that is supplied to the vegetable and fruit room 4, It is the same as the first embodiment. Both sides are supplied to the upper container 73 and the lower container 72 from above.  In the second embodiment, Photocatalyst is also disposed on the bottom surface of the water storage tank 85. Further, a light source that emits ultraviolet rays on the side of the unit housing portion 7 is provided.  In the second embodiment configured as described above, the same operational effects as those of the first embodiment can be obtained.  (Third embodiment) Next, See Figure 9 to Figure 13. A third embodiment of the present invention will be described. In addition, The same portions as those in the first and second embodiments are denoted by the same reference numerals, and the description will be omitted.  The atomizing unit 1 〇 2 ' of the electrostatic atomizing device 10 of the third embodiment is disposed behind the -22-201042224 in which the glove box 1 0 3 is disposed on the upper surface of the partition plate 8 as shown in Fig. 9 . Further, it is located at the right side of the water supply water supply tank 20 and the water receiving container 28. The glove box 203 is formed to have a shorter length in the front-rear direction than the glove box 21 of the first embodiment.  The atomizing unit 102 is as shown in FIG. 11 to FIG. Is equipped with: The unit base 104 fixed to the side of the partition plate 8 With respect to the unit base 104, By sliding from the front, The unit cell is detachably mounted 105° 单元 The unit base 1〇4 is a substantially rectangular box shape forming an upper surface and a front opening. A cover 106 formed in an L shape is provided at the front side as viewed from the side. The cover 106 is formed by forming the following ends as a fulcrum. It can be turned in the front and rear direction. In the cover 1 0 6, In the closed state shown in Figure 11, A notch portion 107 having an opening at the rear end is formed in the upper portion, And a pressing piece 108° notch 107 is provided on the right side portion, It is to avoid interference with the water supply pipe 109 to be described later.  At the upper portion of the right side wall of the unit base 104, A lid switch 1 1 借 that is operated by the pressing piece 108 is provided. The lid switch 1 1 〇 detects the opening and closing of the lid 106.  In the aforementioned unit box 105, As shown in Figure 13. The water storage tank 1 1 1 (equivalent to the water storage part) is integrally provided on the left side. A filter filter for accommodating the ion exchange resin is accommodated in the water storage tank 1 1 1 It is equipped with a float structure 1 1 2 .  Float member 1 1 2, Is with: Buoy part 1 1 3 ;  - the end portion is coupled to the pontoon portion 113 in a slightly L-shaped arm portion 114; And a permanent magnet 丨5 that is fixed to the front end portion of the arm portion 1 1 4, The middle portion of the arm 丨丨 4 is rotatably supported by the shaft -23- 201042224 1 1 6 in the water storage tank 1 1 1 ° where the water level in the 'sink 1 11 is still as shown in Fig. 1 The 'float portion 11 3 is positioned high' and the permanent magnet 11 5 is low. and, When the water level in the water storage tank 11 1 becomes low, As shown in Fig. 1, the position of the pontoon portion 1 1 3 becomes lower as shown by the 3-point lock line, whereby the position of the permanent magnet becomes high.  Two gas sensors 1 17 and 1 18 are provided above and below the left side wall of the unit base 104. Using the magnetic gas sensors 1 17 1 1 buoy member π 2 ' by magnetic sensor 1 17 1 1 8 detects the position of the permanent magnet 1 1 5 of the floating piece 1 1 2, The water level of the water tank 1 1 1 can be detected.  also, By the magnetic gas sensor 117, 118 detects the permanent magnet 11 the presence or absence of the magnetic flux 'whether the detectable unit cartridge 105 is mounted in the unit 104 ° at the upper portion of the unit casing 105 ' the unit cover 120 is detachably provided on the unit cover 120 to be formed in the aforementioned filter filter The upper water injection port 121 of the device 86. The right portion ' of the unit case 1〇5 and the pin holding case 92 of the second embodiment are detachably provided.  The pin holding case 92 is provided with: Conductive sheet 93; a water mist release portion of a plurality of water retaining materials 9 5 ; Water absorption pin 9 1 ; And when the power supply pin is 9 6 The power supply pin 96 is also bent in its lower portion toward the rear, and is generally L-shaped.  and, A front facing connector 122 is provided at the bottom of the unit base 104, The unit case 105 on which the pin holding case 92 is mounted is placed from the front 3 position with the magnetic 8 of both 115 and the base 5 of the inside of the barrel.  The same 94 of the party;  . This is the shape of the square plug -24- 201042224 on the unit base 1 〇4, The front end portion of the power supply pin 96 is formed to be inserted into the connector 1 22 from the front. a lower end portion of the plurality of mist release portions 95, It is located outside the unit box 〖05.  A bottom portion of the unit base 104 is formed below the mist release portion 95. A release port 1 2 3 composed of a plurality of holes. also, In the partition plate 8, A mist discharge port 124 is formed at a portion corresponding to the discharge port 123 (see Fig. 13).  〇 Therefore, At this time, the mist released from the mist release portion 95, The release port 1 2 3 and the mist release port 1 24 ' are supplied to the vegetable and fruit compartment 4 below.  at this time, The atomizing unit 102 of the electrostatic atomizing device 101 is as shown in FIG. The upper left portion of the upper container 73 located in the vegetable compartment 4 is formed. therefore, Each of the mist releasing portions 905 of the atomizing unit 1 〇 2 is formed to face the upper container 73 from above. The mist released from the mist release port 124 is supplied only to the upper container 73.  Ο Therefore, In this embodiment, A plurality of slit-shaped vent portions 156 are formed at the bottom of the upper container 724. With this, The mist supplied to the upper container 73 can be made, It is also supplied to the lower container 72 through the vent portion 1 25 '. Next, Mainly use Figure 9, The automatic water supply structure of the atomization unit 1 0 2 of the electrostatic atomization device 1 进行 will be described. A dedicated water supply mechanism i 27 for the electrostatic atomization device 1 〇 1 is provided in the ice supply water supply tank 20.  The water supply mechanism 1 27 is the same as the aforementioned water supply mechanism 29: a pump motor 128· disposed under the water receiving container 28, With the chestnut -25- 201042224 motor 1 28 is rotated by the permanent magnet t 29 ; a pump 130 that is rotated by a permanent magnet 129 provided to the water tank 20 for ice making; And the water injection port 1 2 1 from the aforementioned atomization unit 102 The water picked up by the pump 130 is led to the water supply pipe 09 of the water storage tank 1 1 1 .  The front end of the water supply pipe 1 0 9 It is facing the water inlet 1 2 1 from above (see Figure 1 1. Figure 1 2). Formed by the water supply mechanism 127, The ice is used to feed the water in the water tank 20, The atomization unit 1 〇 2 is automatically supplied with a configuration of only the required amount. The pump motor 1 2 8 of the water supply mechanism 1 27 is also configured to be controlled by the aforementioned control device 75.  According to the above embodiment, In particular, the following effects can be obtained. 〇 Since the water supply mechanism 127 automatically supplies the water for supplying the ice to the water tank 20 to the atomization unit 102 of the electrostatic atomization device 110,  Therefore, the water supply to the electrostatic atomizing device 1 0 1 can be automated, This saves time-consuming situations in which the user can supply water to the electrostatic atomizing device 1 0 1 one by one. In this embodiment, The ice making water supply tank 20 also serves as a water storage portion of the electrostatic atomizing device 1 0 1 .  The atomizing unit 102 of the electrostatic atomizing device 101, Since it is disposed at the rear of the partition plate 8, Therefore, the water supply path from the ice supply water supply tank 20 to the water supply container 28 is formed. It can make automatic water supply easy.  a mist release portion 9 of the atomization unit 102, Although it is disposed above the upper container 7 3 facing the vegetable and fruit chamber 4, However, since the venting portion 15 is formed at the bottom of the upper container 73, Therefore, the mist released from the mist release portion 95 can be supplied to the upper container 73, And it can also be supplied to the lower container through the vent -26- 201042224 portion 1 2 5 and can be supplied to the lower container 7 2 ° by the pontoon member 112 provided with the permanent magnet 115 in the sump 111 and the magnetic sensation provided at the unit base 104 Detector 117,  11 8 detects the water level in the water storage tank 111. With such a checkout, When the control device 75 detects that the water W in the water storage tank 1 1 1 is not present, Its notification became possible.  also, Since it is detected whether or not the unit case 〇 1 〇 5 is attached to the unit base 丨〇 4, Therefore, when it is judged that the unit case 1 0 5 is not attached to the unit base 104, The electrostatically atomizing device 101 may not be energized.  (Fourth embodiment) Fig. 14 shows a fourth embodiment of the present invention. The fourth embodiment differs from the above-described third embodiment in the following features. that is, A switching valve 132 is provided in an intermediate portion of the water supply pipe 3 3 of the water supply mechanism 29 of the first embodiment. And a branch pipe 133 is provided in the switching valve 132, The front end portion of the 分歧 branch pipe 133 faces the water injection port 1 2 1 of the atomizing unit 1 〇 2 of the third embodiment.  At this time, the water for supplying the ice water supply tank 20 can be supplied to the water receiving container 28 side through the water supply pipe 3 3 ' by the switching valve 132; Switching to the case where the branch pipe 1 3 3 ' is supplied to the atomizing unit 丨〇 2 side. The switching valve 1 32 is also configured to be controlled by the control unit 75.  In the fourth embodiment having such a structure, The same operational effects as those of the third embodiment can be obtained.  -27- 201042224 (Fifth Embodiment) Next, Referring to Fig. 15, a fifth embodiment of the present invention will be described. In addition, The symbols are labeled in the same manner as in the first embodiment. And omitted, Explain the different parts.  The electrostatic atomizing device 1 3 5 of this embodiment, In the rear of the refrigerator compartment 3, Is disposed above the freezing compartment 23, It is located in front of the cold air outlet 15a of the cool air passage 15. The unit base 137 of the atomizing unit 136 that houses the electrostatic atomizing device 135, It is fixed to the lower shelf 138 which is disposed above the freezing compartment 23.  The unit base 137 is open at the rear and the front. And a cover 1 3 9 that opens and closes the front opening portion is provided at the front. Cover 1 3 9, The upper end portion is rotatably supported by the unit base 137 with the shaft 140, It can be rotated in the front-rear direction with its axis 140 as a fulcrum.  A lid switch 141 for detecting opening and closing of the lid 139 is provided at an upper portion of the unit base 137. A stopper portion 1 42 is provided in the lower shelf 138. The stopping portion 1 42 is for restricting the movement of the cover 139 in the opening direction. Formed when the user opens the lid 139, The restrictions can be lifted. A mist discharge port 143 for allowing mist to pass is formed in the cover 139.  The atomization unit 1 3 6 has: Auxiliary slot 1 44, Forming a plurality of pin-shaped mist release portions I45, Conductive sheet M6, Water retention material 147, Water absorbing pin 148, And a release cover 149, Further, the unit base 137 is formed to be detachable from the front side.  Mist release part 1 45, Conductive sheet 1 46, Water retention material 1 47, The water suction pin 148 is the mist release portion 49 of the first embodiment. Conductivity -28- 201042224 Sheet 46, Water retention material 47, Further, the water absorbing pin 48 and the mist releasing portion 145 are upper end portions and the upper end portion having a thin tapered shape is upward. Conductive sheet 146 147. The water absorbing pin 148 is in contact with the upper end portion through the water retaining material 1 46, The lower end is inserted and stored in the auxiliary ί.  One end portion of one end portion of the water absorbing material 150 which is formed of the water retaining material 0 and which is excellent in water absorbability is inserted into the water retaining material 147 and is inserted into the refrigerating cooler 1 portion 151. The water receiving portion 151 is configured to receive defrosting water at the time of defrosting. By the water receiving part 1 5 1 ), Is formed before being supplied to the front through the water absorbing material 150. The water in the water absorbing portion 1 51 is formed in the water retaining material 1 47, And a configuration of water passing through the water absorbing pin 1 4 8 is formed. therefore, The structure of the water in the Q portion 151 of the mist release portion 145 and the water in the auxiliary tank 1 4 8 Water absorbing material 1 50 Water retention material 1 4 7, Conductivity A water supply unit that supplies moisture to the mist release unit 145.  The aforementioned release portion cover 149 is configured to cover a plurality of holes having a mist passing therethrough. The power supply pin I54 exits the atomization unit. As the atomization unit 136 will be simultaneously The power supply pin 154 is inserted into the connector 155 connected to the =137 side. The connector 155 is connected to the negative electrode 157 of the holder 156.  The material of the species is formed.  Sheet 146 is in contact, And the water-repellent material 147 is disposed in the same material as the water-based material 147 in the conductive sheet 144. The water below the other 3 of the water absorbing material 150 receives the water that the chiller cooler 1 3 receives (the defrosting water describes the water retention material 147).  The material 150 is supplied with water to supply the supply tank 144 to form a supplyable water supply. at this time, Water absorbing pin sheet 1 4 6, Is constituted by the mist release portion 145,  The 136 is provided with a rearward projection mounted in a standard position. The wave is placed at the unit base. The DC high voltage power supply is installed -29- 201042224 At this time, In the mist release section 1 45, Formed via the conductive sheet 1 46 , Power supply pin 1 5 4, The connector 155 applies a negative high voltage of the DC high voltage power supply unit 1 5 6 .  When a negative high voltage of the DC high voltage power supply unit 156 is applied to each of the mist discharge units 1 45, By the natural discharge phenomenon occurring in each mist release portion 145, The moisture on the surface of the mist releasing portion 145 is split and the fine mist is released.  Even in the electrostatic atomizing device 135, the counter electrode of the mist releasing portion 145 to which a negative high voltage is applied is not provided.  In the above structure, When the electrostatic atomizing device 135 is driven, A fine mist containing a hydroxyl radical is released from each of the mist releasing portions 145. The mist is passed through the mist discharge port of the cover 139 together with the flow of the cold air blown from the cold air outlet 15a of the cold air passage 15 toward the inside of the refrigerating chamber 3 It is supplied toward the front of the cold storage compartment 3 (see arrow C). The mist supplied into the refrigerating compartment 3 also forms a vegetable and fruit compartment 4 which is supplied to the lower side together with the cold air.  According to the above embodiment, The next effect can be obtained.  In the refrigerating compartment 3, since the electrostatic atomizing device 135 is disposed in front of the cold air blowing port 15 5 a, Therefore, the mist released from the mist release portion 145 can be supplied to the refrigerating chamber 3 and the fruit and vegetable chamber 4, The effects of such sterilization and deodorization can be expected. also, It is also expected that the freshness of fruits and vegetables, etc., can be maintained by the fog.  As the water used in the electrostatic atomization device 135, Since the defrosting water received by the water receiving portion 151 can also be utilized, Therefore, the water supply to the electrostatic atomizing device 1 3 5 can be automated, And can greatly save the user's water supply to the electrostatic fog -30 - 201042224 The device 1 3 5 trouble. In addition, Assisting to store water in the auxiliary tank 144° (Sixth embodiment) Next, Referring to Figures 16 and 17, The sixth embodiment of the present invention will be described. In addition, In the same part as in the first embodiment, Mark the same symbol ’ and omit the description, Explain the different parts.  前 At the front of the refrigerating cooler I3 at the rear of the lower part of the refrigerating compartment 3,  Heat insulation cover 1 60 made of insulation material, A refrigerating cooler cover made of synthetic resin (hereinafter referred to as an "evaporator cover") is provided. ) 161. R evaporator cover 161, It is fixed to the rear of the refrigerating compartment 3 by a screw 162 (see a broken line in Fig. 16). In addition, The mounting part of the screw 16 2, It is covered from the front by a seal 162a.  An opening portion 163 located at a portion corresponding to the front surface of the refrigerating cooler 13 is formed in the heat insulating material cover 160. In front of the R evaporator cover 161, The dew receiving groove 164 is integrally formed with the R evaporator cover 161. In addition, The refrigerating cooler 13 is conventionally provided with: The refrigerant pipe 13a through which the refrigerant passes, And a plurality of pieces of cooling plate 13b, The refrigerant pipe 13a is arranged in a meandering shape.  The dew receiving groove 1 64 is as shown in FIG. Have: Provided in a portion corresponding to the rear portion of the electrostatic atomizing device 36, a longitudinal groove extending in the up and down direction 1 6 5 ; An inclined groove 166 extending obliquely from the longitudinal groove 165 toward the left and right is inclined. Left and right inclined grooves 1 66, Viewed from the side, Formed by L-shaped ribs, The shape of the dew that forms the front of the R evaporator cover -31 - 201042224 1 6 1 is easy to undertake.  The left and right inclined grooves 166 are formed to be inclined downward toward the longitudinal grooves 165, The condensed water 'accepted by the inclined grooves 166 flows toward the longitudinal grooves 165.  The aforementioned partition plate 8 constituting the bottom of the refrigerating compartment 3 is provided with a condensed water guide groove 167 (see Fig. 17). The condensate guiding groove 167 is a rear end portion connected to a lower end portion of the longitudinal groove 165. The front portion of the condensate guiding groove 167 is a lower surface of the cover 40 that is slid into the front-rear direction of the permeable partition plate 8, The front cover extends and is inserted between the unit cover 45 of the electrostatic atomizing device 36 and the cover 40.  at this time, A gap into which the condensate guiding groove 167 can be inserted is formed between the unit cover 45 and the cover 40. An outlet 167a of the front end portion of the condensate guiding groove 167, It is arranged to face the opening portion 168 for water injection formed in the unit cover 45 from above.  In the above composition, Since the opening portion 1 63 is formed in the heat insulating material cover 160 covering the refrigerating cooler 13, Therefore, the cold air cooled by the refrigerating cooler 13 is easily brought into contact with the R evaporator cover 161 through the opening portion 163 thereof. Therefore, the R evaporator cover 161 is easily cooled.  With this cooling, In front of the R evaporator cover 161, Although it is prone to condensation, But it condenses into water droplets, And hang down to the front of the R evaporator cover 1 6 I, And falling condensate, It is received by a tilting groove 16 6 which receives the groove 6 4 from the dew.  The condensed water received by the inclined groove 166, Is formed after flowing toward the longitudinal slot i 65 Through its longitudinal groove 1 65 and condensate guiding groove 67, From the condensate -32 - 201042224, the outlet 167a of the guide groove 167 passes through the opening portion of the electrostatic atomizing device 36. It is supplied onto the conductive sheet 46.  The water (condensed water) supplied to the conductive sheet 46 is also supplied to the mist releasing portion 49', and the mist is released from the mist releasing portion 49. R evaporator cover 1 6 1, Dew receiving groove 1 64, The condensed water guiding groove 167 also constitutes a water supply unit that supplies water to the mist releasing unit □ 〇 according to the above embodiment. Especially as the water used in the electrostatic atomizing device 36, Since the condensed water received by the dew receiving groove 164 of the R evaporator cover 101 is also utilized, Therefore, the water supply to the electrostatic atomizing device 36 can be automated, Moreover, it is extremely troublesome to reduce the user's water supply to the electrostatic atomizing device.  (Seventh embodiment) Ο Next, A seventh embodiment of the present invention will be described with reference to Figs. 18 and 19. In addition, The same portions as those in the sixth embodiment are denoted by the same reference numerals, and the description thereof will be omitted. Explain the different parts.  at this time, The mounting portion ' of the screw 1 62 to which the R evaporator cover 161 is fixed is provided in the vicinity of the refrigerant pipe 13a of the refrigerating cooler 13.  Specifically, the R evaporator cover 161 is as shown in FIG. Located in the vicinity of the left and right inclined grooves 166 of the dew receiving groove 1 64, A cylindrical screw mounting portion i 70 protruding toward the rear is integrally provided. The screw mounting portion 170 is formed through the opening portion I7 of the heat insulating material cover 160. And through the cold -33- 201042224, the vicinity of the medium tube 1 3 a arrives at the rear of the refrigerating chamber 3.  Then, the screw 丨 62 mounted on the screw mounting portion 丨 70 is mounted on , The inner box 1 72 at the rear of the refrigerating compartment 3. Further, 'the seal member i62a' is adhered to the front of the screw mounting portion 丨7 并 and by its seal member 162a, The front opening portion of the screw mounting portion 170 is covered.  In the above configuration, the screw mounting portion 170 for fixing the R evaporator cover 161 is disposed in the vicinity of the refrigerant pipe 13a of the refrigerating cooler 13, Via screw 1 6 2 and screw mounting part i 7 0, r evaporator cover 1 6] is easily cooled 'by this' in front of the R evaporator cover 161, Condensation becomes easy to produce.  Even in the above embodiment, as in the sixth embodiment, Condensate that can condense in front of the R evaporator cover 161, The electrostatic atomizing device 36 is supplied via the dew receiving groove 1 64 and the condensate guiding groove 1 67 '.  therefore, As the water used in the electrostatic atomizing device 36, Since the condensed water received by the dew receiving groove 164 of the R evaporator cover 161 can also be utilized, the water supply to the electrostatic atomizing device 36 can be automated, Moreover, the trouble of the user supplying water to the electrostatic atomizing device 36 can be minimized.  (Eighth Embodiment) Next, an eighth embodiment of the present invention will be described with reference to Figs. 20 and 221. In addition, the same portions as those in the first embodiment are denoted by the same reference numerals, and the description thereof will be omitted. Explain the different parts.  In the upper portion of the water supply tank 80 80 which is disposed on the partition plate 8,  The sink cover 1 8 1 is detachably provided. The ice making water supply tank 1 800, Yes -34- 201042224 Stores the water supplied to the automatic ice making device (ice making device) 1 2 (see Fig. 1) of the ice tray 1 1 and is detachably mounted in the refrigerating chamber 3 on the partition plate 8 . The water supply container 180 for ice making and the water receiving container 28 for the automatic ice making device 12 are provided with the first! In the same manner as the water supply mechanism 29 of the embodiment, the atomization unit 183 of the electrostatic atomization device 182 is provided on the upper surface of the water supply cover 181 (the right portion in Fig. 20). Atomization unit 〇 183, Is equipped with: Unit box 184; a conductive sheet 185 and a water retaining material 1 8 6 disposed in the unit case 184; a water absorbing pin 187 constituting the water absorbing portion; And a plurality of mist release portions 188.  Among them, Conductive sheet 1 8 5, Water retention material 1 8 6 Water absorption pin 1 8 7 , Mist release unit 18 8 It is the conductive sheet 46 of the first embodiment, Water retention material 47, Water absorption pin 48, The same material as the mist release portion 49 is formed.  The water absorbing pin 1 8 7 is formed long in the vertical direction. The upper end portion is in the single unit box 184, The water retaining material 186 is in contact with the conductive sheet 185, The lower end portion is inserted through the water supply tank cover 1 8 1 ' from above into the water supply water supply tank 180. The lower end portion of the water absorbing pin 187 is near the bottom of the ice making water supply tank 180.  The water absorbing pin 187 is particularly excellent in the suction property of water, and sucks up the water in the water tank for the ice water tank. The mist releasing portion 1 8 8 is supplied via the water retaining material 186 and the conductive sheet 1 8 5 .  at this time, Water absorption pin 1 8 7, Water retention material 1 8 6 The conductive sheet 185 is a water supply portion that supplies water to the mist release portion 188. Further, -35-201042224 The water supply tank 180 is a storage portion for storing water supplied to the mist release portion 188.  At the rear of the atomizing unit 183, the electric pin 190, which is branched as shown in Fig. 21, is disposed rearward. The power supply pin 1 9 is electrically connected to the conductive sheet 185 via an electric member (not shown).  In the cold air passage 1 5 existing behind the water supply water supply tank 180, a power supply box 1 9 is provided. A DC commercial voltage power supply 192 is housed in the power supply box 191. The pole pin 193 whose one end is connected to the DC high voltage power supply unit 192 is provided toward the front.  The electrode pin 193 is connected to the negative electrode of the DC high voltage power supply unit 192. A protective cylinder 194 surrounding the electrode pin 139 is provided at the front of the power supply box 191.  at this time, The atomizing unit 183 is disposed on the water tank cover 181, As the ice making is slid from the top to the rear of the water tank 180 (to the right from the left to the right), the regular position on the partition plate 8 is slid, Inserting the power supply pin 1 90 of the atomizing unit 1 83 into the protective cylinder portion 1 94 A state in which the electrode pins of the DC high-voltage power supply device 1 9 2 are electrically and mechanically connected is formed.  In the connected state, The mist release portion 8 8 of the atomization unit 1 8 3 is from the DC high voltage power supply device 1 92 via the electrode pin 1 93, Power supply 1 90 Conductive member not shown, The conductive sheet 185 applies a negative high voltage (_4~_l〇kV), With this, A fine mist is released from the mist release portion 188.  In the unit box 184, a discharge port 1 - 5 5 is formed in the lower direction water supply of the mist discharge portion 1 8 8 to be electrically connected to the mounted electrical connection state - 36 - 201042224. The mist released from the mist release portion 1 8 8 , It is formed from the discharge port 1 95 thereof to be supplied into the refrigerating compartment 3. In addition, When the ice is removed from the installation position and the front side is slid, The connection of the power supply pin 190 to the electrode pin 193 is released.  According to the above embodiment, In particular, the following effects can be obtained. 〇 The atomizing unit 183 of the electrostatic atomizing device 182 is placed on the water supply cover 1 8 1 for the ice making tank 190 Inserting the water absorbing pin 1 8 7 of the atomizing unit 1 8 3 into the water supply sink 180 Further, a configuration is adopted in which the water in the water supply tank 180 for sucking up the water absorbing pin 187 is supplied to the mist releasing portion 188, whereby It is also possible to use the water supply tank 80 as the water storage unit of the electrostatic atomization device 1 8 2 . And by the water supply operation for the ice making tank for the water tank, Water can be supplied to both systems of the automatic ice making device 12 and the electrostatic atomizing device 182. It can improve the workability of the water supply operation.  Oh, again, The electrostatic atomizing device 182' can be utilized as a water storage portion for the ice making water tank 18 ,. So there is no need to set up a water storage unit. There is an advantage that the setting space can be made small.  (Ninth Embodiment) Next, Referring to Fig. 22', a ninth embodiment of the present invention will be described. In addition, The same portions in the first embodiment are denoted by the same reference numerals.  And the explanation is omitted. Explain the different parts.  In the fruit and vegetable room 4, Below the partition plate 8 (below the bottom plate 37 for electrostatic atomization device -37-201042224 3 6), a cover 200' is provided along the partition 8 of the region and the cover 200 is The space between the partition plate 8 and the bottom plate 3 serves as a cold air passage 201. The cold air passage 201 is, for example, indicated by an arrow D, and can be cooled from the rear of the vegetable compartment 4 toward the front. The plastic bottle 202 or the like stored in the front portion of the vegetable and fruit chamber 4 is sent to cool the cold air for use.  and, The lower bottom plate 37 is disposed at the lower mist release port 203 of the atomizing unit 38. The mist release port 203 is located below the mist release portion 49 of the atomization unit 3 (see Fig. 6 for reference). It’s almost right now, And disposed in a position facing the aforementioned cold air passage 201 from above, in the above configuration, When the mist is released from the mist release portion 49 of the atomizing unit 38, The mist is released from the mist release port 203 of the bottom plate 37, and the cold gas passage 201 is released. In the cold air passage 201, the air is cooled from the rear toward the front (see arrow D). It flows toward the front of the fruit and vegetable compartment 4 and is supplied into the fruit and vegetable compartment 4.  At this time, the mist release port 203 is located directly below the mist release portion 49. And since the cold air path 201 is faced from above, Therefore, the mist released from the mist release portion 49 can be extremely collided against the surface of the bottom plate 37, and the like. It is possible to prevent the fog from adhering to the inner bottom surface of the bottom plate 37 as much as possible.  Further, the mist released from the mist release portion 49, Since the cold air passage 20 1 is sucked into the cold air flowing forward from the rear portion, it is easy to flow out to the cold air passage 2 0 1 side. Moreover, it is possible to suppress the occurrence of collision of the mist with the inner bottom surface of the 37, and the like. And there is a picture 22 that can blow more faces and 丨7, As a party ; The 8 bit is set.  Release the flow to give a rough force to the inner bottom and reduce the shape.  Fog of the bottom plate -38- 201042224 The advantage of flying 1 to the inside of the vegetable and fruit room 4.  BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a longitudinal side view showing the entire refrigerator according to a third embodiment of the present invention.  [Circle I 2 ] g is a schematic perspective view of the vicinity of the electrostatically atomizing device. [Fig. 3] A schematic plan view of the vicinity of the electrostatically atomizing device is provided. [W 4] Vertical of the water supply mechanism portion Broken side view.  Fig. 5 is a schematic perspective view showing the positional relationship between the vegetable container and the electrostatic atomization device.  Fig. 6 is a longitudinal side view of the setting portion of the electrostatically atomizing device.  Fig. 7 is a longitudinal side view of the portion of the electrostatically atomizing device at a different position from Fig. 6.  Fig. 8 is a longitudinal sectional front view showing a portion of the electrostatic atomization device according to the second embodiment of the present invention.  Fig. 9 is a view corresponding to Fig. 5, showing a diagram corresponding to the third embodiment of the present invention shown in Fig. 3;  Fig. 11 is a perspective view showing the outline of an electrostatic atomization device in a state in which the lid is closed.  [Fig. 1 2] A perspective view showing the outline of the electrostatic atomization device in a state in which the cover is opened.  -39- 201042224 [Fig. 13] A longitudinal front view of the electrostatic atomization device.  [Fig. 14] Fig. 14 is a perspective view showing a portion of the electrostatic atomization device according to a fifth embodiment of the present invention. Fig. 15 is a longitudinal side view showing a portion of the electrostatic atomization device according to the fifth embodiment of the present invention.  Fig. 16 shows a sixth embodiment of the present invention. In the state where the freezer box or the like is deleted, A view of the lid portion of the refrigerating cooler is viewed from the front.  Fig. 17 is a longitudinal sectional side view taken along line XI-XI of Fig. 16.  Fig. 18 shows a seventh embodiment of the present invention corresponding to Fig. 16.  Fig. 19 is a longitudinal sectional side view taken along line X2_X2 of Fig. 18.  Fig. 20 is a longitudinal sectional side view showing an installation portion of an electrostatic atomization device according to an eighth embodiment of the present invention.  [Fig. 21] A longitudinal side view of a portion of a power supply device of an electrostatically atomizing device.  Fig. 22 is a view showing a ninth embodiment of the present invention corresponding to Fig. 1 [Description of main component symbols] 3 : Cold storage room (storage room) 4 : Fruit and vegetable room (storage room) 8 : Area partition 1 2 : Automatic ice making device (ice making device) 13: Refrigerator cooler (cooling 1) 15a : Air-conditioning outlet 2 0 : Water supply tank (water storage unit) -40- 201042224 29 '·Water supply mechanism 3 6 : Electrostatic atomization device 3 8 : Atomization unit 40: Cover 43 : Water storage tank (water storage part) 46 : Conductive sheet (water supply unit) 47 : Water retention material (water supply department) 〇 48 : Water absorption pin (water supply) 49 : Fog release 54 : Power supply pin 5 6 : DC high voltage power supply unit 62 : Cover switch 65 : Filter filter 66 : Ion exchange resin 72 : Lower container Ο 73 : Upper container 75 : Control device 7 7 : Electrostatic atomization device 7 8 : Atomization unit 81: Cover 82: Cover switch 8 5 : Water storage tank (water storage part) 8 6 : Filter filter 8 7 : Ion exchange resin -41 201042224 91 : Water absorption pin (water supply) 93 : Conductive sheet (water supply unit) 94 : Water retention material (water supply department) 95 · 'Mist release part 96 : Power supply pin 1 〇 1 : Electrostatic atomization device 1 〇 2 : Atomization unit 106: Cover 1 1 1 : Water storage tank (water storage part) 1 2 5 : Ventilation 1 2 7 : Water supply agency 1 3 2 : Switching valve 1 3 5 : Electrostatic atomization device 1 3 6 : Atomization unit 139: Cover 1 4 1 : Cover switch 1 44 : Auxiliary tank (water storage part) 145 : Fog release 146 : Conductive sheet (water supply unit) 1 4 7 : Water retention material (water supply department) 1 4 8 : Water absorption pin (water supply) 1 5 0 : Water absorbing material (water supply department) 1 5 1 : Water receiving part (water storage part) 1 5 4 : Power supply pin -42- 201042224 1 5 6 : Power supply unit 1 6 1 : Refrigerator cooler cover (R evaporator cover (water supply)) 164 : Dew receiving groove (water supply) 167 : Condensate guiding groove (water supply part) 1 8 0 : Ice making water supply tank (water storage part) 182 : Electrostatic atomization device 1 8 3 : Atomization unit Ο 1 8 5 : Conductive sheet (water supply unit) 1 8 6 : Water retention material (water supply department) 1 8 7 : Water absorption pin (water absorption part, Water Supply Department) 1 8 8 : Fog release 2 0 1 : Cold air meets 2 0 3 : Mist release port 〇 -43-

Claims (1)

201042224 VII. Patent application scope: 1. A refrigerator is a refrigerator having a storage compartment in a refrigerating temperature zone, and is characterized in that: an electrostatic atomization device is provided, the electrostatic atomization device has a mist release portion; a water supply unit of the mist release unit; and a structure for applying a negative high voltage to the mist release unit, and releasing a DC high voltage power supply device for mist from the mist release unit by discharge generated in the mist release unit. A structure is formed in which the mist released from the mist release portion is supplied to the storage chamber. 2. The refrigerator according to the first aspect of the invention, wherein the electrostatic atomization device has a water storage portion for storing water, and the water supply portion supplies water stored in the water storage portion to the mist release portion. 3. The refrigerator according to claim 2, wherein the water storage unit is a detachable tank. 4. The refrigerator according to the third aspect of the invention, wherein the mist discharge unit is detachable when the water storage unit is attached or detached. 5. The refrigerator according to claim 2, wherein the water storage unit is provided with an ion exchange resin. 6. The refrigerator according to the first aspect of the invention, wherein the storage compartment includes a refrigerator compartment and a vegetable compartment disposed below the refrigerator compartment via a partition panel, and the electrostatic atomization device is installed. In front of the aforementioned zone partition. The refrigerator according to claim 6, wherein the vegetable and fruit compartment includes: a lower container; and an upper container disposed on an upper portion of the lower container and smaller than the lower container, The mist released from the mist release portion is supplied to both the upper container and the lower container from above. The refrigerator according to the first aspect of the invention, wherein the refrigerator is provided with an ice making water tank for storing water supplied to the ice making device, and the water for supplying the ice water to the water tank is supplied to the electrostatic atomization. The composition of the water supply unit of the device. 9. The refrigerator according to claim 8, wherein the storage compartment includes a refrigerating compartment and a vegetable compartment disposed below the refrigerating compartment via the compartment partition, and the ice making water supply tank is The detachable surface is disposed in the partition plate, and the electrostatic atomizing device is disposed at a rear portion of the partition plate. 10. The refrigerator according to claim 9, wherein the vegetable compartment has a lower container and an upper container disposed at an upper portion of the lower container, wherein the mist release portion is configured to be from above. In the upper container, a venting portion is formed in the upper container. 11. The refrigerator according to claim 1, wherein the refrigerator is provided as the storage compartment, and the electrostatic atomization device is disposed in front of a cold air outlet for blowing cold air to the refrigerator compartment. 12. The refrigerator according to claim 1, wherein -45 to 201042224 includes a cooler on a back surface of the refrigerator compartment, and a water receiving defrosting water for receiving the cooler below the cooler In the water supply unit of the electrostatic atomization device, the water in the water receiving portion is supplied to the mist release unit. The refrigerator according to the first aspect of the invention, comprising: a water supply tank for storing ice supplied to the ice making device, wherein the water supply unit of the electrostatic atomization device is provided with the water supply for ice making In the water absorbing portion in the tank, the water in the water tank for sucking the water sucking portion is supplied to the mist releasing portion. 14. The refrigerator according to the first aspect of the invention, wherein the storage compartment is provided with a refrigerator compartment and a vegetable compartment disposed below the refrigerator compartment via the compartment partition, wherein the electrostatic atomization device is Provided in the partition plate, a cold air passage for allowing cold air to flow along the lower surface of the partition plate to the vegetable and fruit chamber under the partition plate, and being released from the mist release portion of the electrostatic atomization device The mist is released to the mist release port of the vegetable and fruit compartment, and is a position provided below the mist release portion and facing the cold air passage from above. 15. The refrigerator according to claim 1, wherein the nano platinum microparticle colloid is attached to the mist release portion. 16. The refrigerator according to claim 1, wherein the mist releasing portion includes a conductive material. 17. The refrigerator according to claim 1, wherein the opening of the storage compartment is interrupted by the opening of the electrostatic atomizing device. The refrigerator according to the first aspect of the invention, wherein the electrostatic atomizing device is capable of opening and closing the lid, and blocking the energization of the electrostatic atomizing device when the lid is opened. -47-