RU2426960C2 - Refrigerator - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: refrigerator includes storage compartment, mist sprayer arranged in storage compartment, drying device to dry mist sprayer. Mist sprayer condenses moisture in air in storage compartment and sprays it to storage compartment in the form of mist.

EFFECT: effective accumulation of evaporated moisture from stored food products, sufficient humidification of inner part of container and higher freshness characteristic.

9 cl, 26 dwg

Description

FIELD OF THE INVENTION

The present invention relates to a refrigeration unit with a storage compartment in which high humidity is maintained.

BACKGROUND OF THE INVENTION

Temperature, humidity, the gaseous component of the environment, microbes, light and the like are factors that reduce the freshness of vegetables. Vegetables are living matter that performs the function of gas evolution (“respiration”) and transpiration, and to maintain freshness, the function of gas evolution and transpiration must be suppressed. In addition, in most vegetables other than vegetables in which a low temperature causes defects, gas evolution ceases at a low temperature and high humidity prevents evaporation. In recent years, the home refrigerator includes a sealed container dedicated to storing vegetables, and is adjusted so that the vegetables are cooled to the proper temperature, and the inside of the refrigerator has high humidity to inhibit transpiration of vegetables for their preservation. Means for spraying fog (finely divided liquid) can be used as a means of maintaining high humidity in the interior of the refrigerator.

Traditionally, a refrigerator having such a function of spraying a mist creates and sprayes a mist by vibrating the absorbent material with an ultrasonic generator and moisturizes the inside of the vegetable compartment to prevent transpiration of the vegetables.

On Fig shows a longitudinal section of a traditional refrigerator. As shown in FIG. 23, the isothermal cabinet (refrigerator case) 201 includes a refrigerator compartment 202, and the opening of its front surface is closed by a door 203. The vegetable compartment 204 is located below the refrigerator compartment 202, and the opening on its front surface is closed by an opening door 205. The freezer compartment 206 is located below the vegetable compartment 204, and the opening on its front surface is closed by an opening door 207. The refrigerator compartment 202 and the vegetable compartment 204 are separated by a partition panel 208. The partition panel 208 encloses an opening 209 for the penetration of cold air from the refrigerator compartment 202 into the vegetable compartment 204. The vegetable container 210 is attached to the opening door 205 and extends when opening / closing the opening door 205. The lid 211 of the vegetable container is located in the upper part of the container 210 for vegetables to close the container 210 for vegetables when the opening door 205 is closed. Here, the lid 211 of the vegetable container is fixed to the side of the refrigerator body. The lid 211 of the vegetable container incorporates an ultrasonic humidifier 212 to release moisture into the interior of the vegetable container 210. The refrigerator compartment 202 includes an evaporator 213 for separating with a temperature cooling zone to circulate cold air by the action of the fan 214 and to cool the refrigerator compartment 202 and the vegetable compartment 204. Although not shown in the drawings, the refrigerator also includes an evaporator for a compartment with a temperature freezing zone to cool the freezer compartment 206.

On Fig shows a cross section of the vicinity of the traditional ultrasonic humidifier 212. As shown in Fig, the ultrasonic humidifier 212 is located in the hole 215 of the cover 211 of the vegetable container and is formed by water-absorbing material 216 and an ultrasonic generator 217.

Below will be described the operation of the refrigerator having the configuration as described above. When the temperature of the refrigerator compartment 202 / compartment 204 for vegetables becomes high, the cooling medium is flowed to the evaporator 213, and the fan 214 is driven. As shown by the arrow in FIG. 23, the cooling air at the periphery of the evaporator 213 then returns to the evaporator 213 through the refrigeration compartment 202, the opening 209 and the vegetable compartment 204. The refrigerator compartment 202 and the vegetable compartment 204 are thereby cooled. This condition is called cooling mode.

When the refrigeration compartment 202 / vegetable compartment 204 is substantially cooled, the supply of cooling medium to the evaporator 213 is stopped. However, the fan 214 continues to operate. Thus, the refrigeration compartment 202 / compartment 204 for vegetables are moistened by melting frost on the evaporator 213. This condition is called the humidification mode. Humidification mode is also called "moisture movement". The fan 14 stops after a predetermined time (within several minutes) of the humidification mode, which is the stopped operation mode. After that, when the temperature of the refrigerator compartment 202 / compartment 204 for vegetables becomes high, the cooling mode again becomes a state. The above modes are repeated.

An ultrasonic humidifier 212 will now be described. Desiccant 216 is made of a moisture-absorbing material such as silica gel, zeolite, activated carbon, and the like. Therefore, moisture in moving air is absorbed in the humidification mode described above. The ultrasonic generator 217 is driven in the second half of the cooling mode. The moisture in the desiccant 216 is thereby released to the outside. The inside of the vegetable container 210 is wetted as a result. The ultrasonic generator 217 is driven in the second half of the cooling mode to prevent drying due to a decrease in humidity in the vegetable compartment 204.

In the traditional configuration, the upper surface of the vegetable container 210 is closed by the lid 211 of the vegetable container, whereby the inside of the vegetable container 210 is difficult to moisten even if cold air containing moisture is circulated through the vegetable compartment 204 during the humidification mode (during the movement of moisture ) In addition, in the traditional configuration, moisture in the air of the refrigerator compartment 202 and moisture in a space other than the vegetable container 210 from the vegetable compartment 204 is used as a source of water supply to the ultrasonic generator 217. Most of the moisture in the space is created from warm moisture, which enters the refrigerator when the door is opened / closed, the moisture volume being small compared to the inside of the vegetable container 210 storing vegetables with a large amount of moisture, and thus may probably not enough moisture.

On Fig shows a section of the compartment for vegetables of another traditional refrigerator. As shown in FIG. 25, the vegetable compartment 241 is located in the lower part of the cabinet 246 of the cabinet 240 of the refrigerator, and the opening on its front surface is closed by an opening door 242 that can freely open / close. The vegetable compartment 241 is separated from the refrigerator compartment (not shown) by a partition panel 222 on its upper side. The mounting frame 243 is attached to the inner surface of the opening door 242, and the container 221 for storing food products such as vegetables is mounted on the mounting frame 243. The hole on the upper surface of the container 221 for vegetables is hermetically sealed with a lid 223. A compartment 224 for thawing (thawing) is located inside the container 221, and the ultrasonic atomizing device 225 is located in the thawing compartment 224.

FIG. 26 is a perspective view of an ultrasonic spray device 225. As shown in FIG. 26, the ultrasonic spray device 225 includes a mist ejection port 236, a water storage tank 237, a humidity sensor 238, and a hose receiver 239. A water storage tank 237 is connected via a hose receiver 239 to a thawed water hose 230 (see FIG. 25). A cleaning filter 231 for cleaning thawed water is located in one part of the thawed water hose 230.

Now, the operation of the refrigerator having the configuration as described above will be described. Cooling air cooled by means of a heat exchange evaporator (not shown) moves along the outer surface of the vegetable container 221 and the lid 223 to cool the vegetable container 221 and cool the food products stored therein. Thawed water, which is formed from the evaporator during the operation of the refrigerator, is cleaned by a filter 231 when passing through a hose 230 for thawed water and is supplied in an ultrasonic spray device 225 to a tank 237 for storing water.

If the humidity sensor 238 determines that the humidity inside the refrigerator is lower than or equal to 90%, the ultrasonic atomizing device 225 starts humidification to bring the humidity to the proper humidity to preserve vegetables, etc. in a vegetable container 221 fresh. If the humidity sensor 238 determines that the humidity inside the refrigerator is higher than or equal to 90%, the ultrasonic atomizing device 225 stops excess humidification. As a result, the inside of the vegetable compartment 241 can be quickly moistened with an ultrasonic spray device 225, the inside of the vegetable compartment 241 can always be kept with high humidity, the excretory effect of vegetables, etc. may cease, and freshness of vegetables, etc. may be maintained.

However, in the traditional configuration described above, the atomized water particles cannot be finely ground due to the water atomization system using the ultrasonic vibrating element, and thus the inside of the refrigerator cannot be irrigated uniformly, and the degree of adhesion (surface interaction) of the fog to the surface of the food is low. In addition, if the spray volume is increased or continuous spraying is performed to increase the degree of adhesion, vegetables, etc. tend to deteriorate, or the inside of the refrigerator may create condensation.

In addition, the traditional configuration described above requires equipment for a thawed water hose and a purification filter, or a water supply path directly connected to the water conduit, and a defrost heater, etc., is required, in which the configuration is complicated.

In addition, in the above-described traditional configuration, the mist is sprayed to obtain high humidity in the interior of the refrigerator, but the spray volume cannot be controlled, whereby water funnels can form in the refrigerator due to over-spraying, and stored items such as vegetables can deteriorate .

[Patent Document 1] Publication of Japanese Unexamined Patent No. 2004-125179

[Patent Document 2] Publication of Japanese Unexamined Patent No. 6-257933

[Patent Document 3] Publication of Japanese Unexamined Patent No. 2000-220949

SUMMARY OF THE INVENTION

In view of the solution to the problems of the prior art, the present invention provides a refrigerator capable of sufficiently humidifying an appropriate amount. The refrigerator according to the present invention includes a thermally insulated, sectioned storage compartment, a set of containers located in the storage compartment, and a mist spray located in the storage compartment. The mist atomizer condenses moisture in the air and atomizes it into the storage compartment as a mist. A mist spray is located near the gap between the containers. According to this configuration, moisture leaked from the inside of the container is efficiently collected and returned to the inside of the container from the gap between the containers by means of a mist sprayer. Thus, the refrigerator according to the present invention sufficiently moisturizes the inside of the container and preserves the freshness of vegetables.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is a front view of a refrigerator according to a first embodiment of the present invention;

2 is a front view of a refrigerator according to a sixth embodiment of the present invention;

3 is a front view of a refrigerator according to a fifth embodiment of the present invention;

4 is a front view of a refrigerator according to a fifth embodiment of the present invention;

5 is a front view of a refrigerator according to a third embodiment of the present invention;

6 is a front view of a refrigerator according to a seventh embodiment of the present invention;

7 is a front view of a refrigerator according to an eighth embodiment of the present invention;

Fig. 8 is a view showing a longitudinal section of a refrigerator according to a first embodiment of the present invention;

9 is a view showing a longitudinal section of a refrigerator according to a second embodiment of the present invention;

10 is a view showing a longitudinal section of a refrigerator according to a third embodiment of the present invention;

11 is a view showing a longitudinal section of a refrigerator according to a fourth embodiment of the present invention;

12 is a view showing a longitudinal section of a refrigerator according to a fifth embodiment of the present invention;

13 is a view showing a longitudinal section of a refrigerator according to a sixth embodiment of the present invention;

14 is a view showing a longitudinal section of a refrigerator according to a seventh embodiment of the present invention;

FIG. 15 is a perspective view of a vegetable compartment according to a fifth embodiment of the present invention; FIG.

FIG. 16 is a perspective view of a vegetable compartment according to a sixth embodiment of the present invention; FIG.

17 is a perspective view of a vegetable compartment according to a seventh embodiment of the present invention;

Fig. 18 is a perspective view of a vegetable compartment according to an eighth embodiment of the present invention;

Fig. 19 is a front view of a vegetable compartment according to a ninth embodiment of the present invention;

FIG. 20 is a detailed cross-sectional view of a mist atomizer region according to a ninth embodiment of the present invention; FIG.

FIG. 21 is a flowchart of a mist atomizer according to a ninth embodiment of the present invention; FIG.

FIG. 22 is a cross-sectional view of a region of a vegetable compartment according to a tenth embodiment of the present invention; FIG.

23 is a view showing a longitudinal section of a conventional refrigerator.

24 is a structural diagram of an ultrasonic humidifier of a conventional refrigerator.

25 is a view showing a longitudinal section of a conventional vegetable compartment;

26 is a perspective view of a conventional ultrasonic atomizing device.

REFERENCE POSITIONS ON THE DRAWINGS

21 - refrigerator compartment

22 - temperature-controlled compartment

23 - ice maker

24 - vegetable department

25 - freezer compartment

28 - cooling compartment

45 - outlet for the vegetable compartment

46 - inlet for the vegetable compartment

64 - bottom container

65 - upper container

66 - cover

67 - mist spray

68 - rib direction of air flow

69 - recess

168 - auxiliary rib air direction

PREFERRED EMBODIMENTS FOR CARRYING OUT THE INVENTION

(First Embodiment)

1 is a front view of a refrigerator according to a first embodiment of the present invention, and is a view of a state in which a door is detached. FIG. 8 shows a longitudinal cross section of a refrigerator according to a first embodiment. In Fig. 1 and Fig. 8, the configuration of the refrigerator body 1 is constituted by the outer wall 18 and the inner wall 19, which are filled from the inside with foam heat-insulating material 20, such as solid (rigid) foam, and insulated from the outside and divided into many storage compartments. The refrigeration compartment 21, used as the first storage compartment, is located on the upper level, the temperature-switched compartment 22, used as the fourth storage compartment, and the ice maker 23, used as the fifth storage compartment, are located adjacent to directly below the refrigeration compartment 21, vegetable compartment 24, used as the second storage compartment, is located directly below the temperature-controlled compartment 22 and the ice maker 23, and the freezer section s 25, is used as a third storage compartment, located at the lowest level.

The refrigerator compartment 21, as a lower limit for cooling, typically has a temperature between 1 ° C and 5 ° C at which freezing does not occur. The vegetable compartment 24 often has a temperature setting between 2 ° C and 7 ° C, which is the same with the refrigerator compartment 21 or slightly higher than that. The freshness of vegetables with leaves (greens) may persist for a long period of time at a lower temperature. The freezer compartment 25 is set to the freezing temperature zone and is usually set between -22 ° C and -15 ° C for storage in a frozen state, but can be set to a low temperature between -30 ° C and -25 ° C to enhance the condition frozen storage.

The temperature-controlled compartment 22 can switch to a temperature zone set in advance between the cooling temperature zone and the freezing temperature zone other than the cooling temperature zone set between 1 ° C and 5 ° C, for vegetables set between 2 ° C and 7 ° C, and for freezing, usually set between -2 ° C and -15 ° C. For example, the temperature between the refrigerator and the freezer compartment for mild low-temperature operation (approximately between -12 ° C and -6 ° C), partial freezing (approximately between -5 ° C and -1 ° C), chilled products (between approximately -1 ° C and 1 ° C) etc. The temperature-switched compartment 22 is a storage compartment including an independent door provided adjacent to the ice maker 23, and often has a drawer type door.

In the present embodiment, the temperature-switched compartment 22 is a storage compartment having a temperature zone of cooling and freezing, but may be a storage compartment adapted to switch only to a temperature zone between cooling and freezing, wherein cooling is assigned to the refrigeration compartment 21 and the vegetable compartment 24. and freezing rests on the freezer compartment 25.

An ice maker 23 is a space in the refrigerator compartment 21 for making ice using an automatic ice maker (not shown) provided in the upper part of the compartment with water supplied from a water tank (not shown) and storing it in an ice storage container ( not shown) located at the bottom of the compartment and is a storage compartment with an independent door with a small opening provided next to the temperature-controlled compartment 22, and often includes a pull-out door th type.

A portion of the roof surface (coating) of the refrigerator body 1 has a shape provided with a stepped recess towards the rear surface of the refrigerator, where an aggregate compartment 26 is arranged in the stepped groove to accommodate the high pressure side components of the freezing cycle, such as compressor 27 and a desiccant (dehumidifier) ) (not shown) to remove moisture. In other words, the aggregate compartment 26, equipped with a compressor 27, is included as part of the rear area on the upper part in the refrigeration compartment 21. Since the aggregate compartment 26 is provided and the compressor 27 is located in the rear region of the storage compartment on the upper part of the refrigerator body 1, which is “dead” »Space, hard to reach, the space of the aggregate compartment, which in a conventional refrigerator was located in the lowest part of the body of the refrigerator 1, which is convenient for the user, can be effectively razovano in capacity storage compartment, thereby significantly improving the containment characteristics and ease of use.

Issues related to the main parts of the invention described below in the present embodiment can be applied to a refrigerator of the type in which an aggregate compartment is provided in the rear region of the storage compartment in the lowermost part of the refrigerator body 1, which was typical in the prior art, and compressor 27 is located therein.

The cooling compartment 28 is located on the rear surface of the vegetable compartment 24 and the freezing compartment 25, the cooling compartment 28 being separated from the vegetable compartment 24 and the freezing compartment 25 by a first cooling channel 29 having heat-insulating ability. The tube-fin type evaporator 30, as a typical representative, is located in the cooling compartment 28. A cooling fan 31 for blowing cold air cooled by the evaporator 30 towards the refrigeration compartment 21, which is switched by the temperature of the compartment 22, the ice maker 23, the vegetable compartment 24 and the freezer compartment 25 by means of forced convection, is located in the upper space of the evaporator 30. A radiation heater 32, made of a glass tube, used as a device for thawing frost adhering to the evaporator 30, and the cooling fan 31 are located in neither It evaporator space 30.

A sealing material, such as soft foam, is attached to the outer surface of the first cooling channel 29 so that cold air and water do not leak. The first partition 33 for separating the freezer compartment 25 and the vegetable compartment 24 is molded with heat-insulating material, such as polystyrene foam, and is removable.

The second partition 34 for separating the temperature-switched compartment 22, the ice maker 23 and the vegetable compartment 24 has an outer shell, the configuration of which is the upper panel 35 of the second partition having a substantially L-shape in lateral cross section, and the lower panel 36 of the second partition in the form a flat plate, and the inside of the second partition 34 is a foam filled with foam thermal insulation material 20, such as solid foam. In this case, the temperature-controlled compartment 22 and the ice maker 23, set to a temperature lower than the vegetable compartment 24, are located above the vegetable compartment 24, where the vegetable compartment 24 is indirectly cooled from above, and the second lower partition panel 36 acts as a cooling panel.

The second cooling channel 38, molded with heat-insulating material 37, such as polystyrene foam, and made with an air duct blown with cold air to cool the refrigerator compartment 21, switched by the temperature of the compartment 22, and an ice maker 23, is located on the rear surface of the upper panel 35 of the second partition essentially L-shaped. The double damper 39, which is used as a regulator to regulate the flow of cold air for the refrigerator compartment 21 and temperature-controlled compartment 22, is located inside, and the used space can be miniaturized, and the cost can be reduced as a result of the availability of a regulator to adjust accordingly the flow of cold air for refrigeration compartment 21 and temperature-controlled compartment 22 in the form of a double damper.

The third partition 40 for separating the refrigerating compartment 21 and the temperature-controlled compartment 22 and the ice maker 23 has an outer shell, the configuration of which is the upper panel 41 of the third partition and the lower panel 42 of the third partition, and the inner part of the third partition 40 is filled with foam of foam thermal insulation material 20, such as solid foam. A third cooling channel 43 for blowing cold air into the refrigerator compartment 21 is attached to the rear surface of the refrigerator compartment 21, and sealing material is attached to the connecting surface of the third cooling channel 43 and the second cooling channel 38 so that cold air and water do not leak. The first cooling channel 29, the first partition 33 and the third cooling channel 43 are removable, but the second partition 34, the second cooling channel 38 and the third partition 40 are not removable, since they are attached before the foam urethane of the refrigerator body 1 and are rigidly attached to the refrigerator case 1 with a foam insulation material 20.

An air duct 91 for blowing cold air to cool the refrigerator compartment 21, a temperature-controlled compartment 22, an ice maker 23 and a freezer compartment 25 is located inside the first cooling duct 29. In addition, a return duct (“connection”) for the refrigerator compartment is provided, to return cold air from the refrigeration compartment 21 to the evaporator 30, a return duct 93 for the temperature-controlled compartment to return cold air from the switchable compartment 22 to the evaporator 30 and a return duct 94 for an ice maker for returning cold air from the ice maker 23 to the evaporator 30. An outlet 45 is provided at the top of the first cooling channel 29 for the vegetable compartment to introduce some of the cold air moving through the return duct 92 for refrigeration compartment, into the vegetable compartment 24. The outlet 45 for the vegetable compartment is made in the form of cooling means for cooling the container. The inlet opening 46 for the vegetable compartment, designed to return cold air from the vegetable compartment 24 again to the return duct 92 for the refrigerator compartment, is located in the position corresponding to the lower part of the vegetable compartment 24 of the first cooling channel 29. The first outlet 47 for the freezer compartment and the second the outlet 48 for the freezer compartment, designed for the entry of cold air from the duct 91 into the freezer compartment 25, are made in positions corresponding to yl compartment 25 to the first cooling channel 29. The inlet port 49 for the freezing compartment, intended for the return of cold air from the freezer compartment 25 to the evaporator 30, disposed in the lower portion of the first cooling channel 29.

The second cooling channel 38 includes a refrigerator compartment duct 50 for blowing cold air toward the refrigerator compartment 21 through the double damper 39, duct 51 for a temperature-controlled compartment for blowing cold air toward the temperature-controlled compartment 22 through the same double damper 39 and the outlet 52 for the temperature-controlled compartment, designed to discharge cold air into the temperature-controlled compartment 22. Also the air duct 53 for the ice maker, directly connected from the air duct 91, for blowing cold air towards the ice maker 23, and the outlet 54 for the ice maker to discharge cold air to the ice maker 23 are formed. The return duct 55 for temperature-controlled separation is also performed designed to return cold air from the temperature-controlled compartment 22 to the evaporator 30, return duct 56 for an ice maker, designed to return cold th air from the icemaker 23 to the evaporator 30, the duct 57 and feeding back to the refrigerator compartment, intended for the return of cold air from the refrigerating compartment 21 to the evaporator 30.

The third cooling channel 43 includes a refrigerator compartment duct 58 to direct cold air to the refrigerator compartment 21, and a plurality of refrigerator compartment outlets 59 for discharging cold air from the refrigerator compartment duct 58 to the refrigerator compartment 21. Inlet 60 for the refrigeration compartment and the return duct 61 for the refrigeration compartment, designed to return cold air from the refrigeration compartment 21 to the evaporator 30, are performed in the lower parts of the third cooling channel 43.

The vegetable compartment 24 is closed by a door 62 with the ability to open the opening on the front surface so that external air does not enter. The door 62 includes a pair of left and right plate rails 63 projecting into the vegetable compartment 24, and a lower container 64 is mounted on them. To open and close, the door 62 extends horizontally along the movable direction of the rail 63, and the lower container 64 is also brought into action and advances with it. The upper container 65 is mounted on the lower container 64 and moves simultaneously with the lower container 64. In this case, the surface area of the base of the upper container 65 is less than the surface area of the base of the lower container 64. In the present embodiment, the upper container 65 and the lower container 64 are located with the space in front and from the back so that relatively high food items such as polyethylene terephthalate (PET) bottles and long vegetables, including Chinese cabbage, can fit. The lid 66 is located in the vegetable compartment 24, the open portion of the upper surface of the upper container 65 being closed when the door 62 is closed. In addition, the lid 66 remains in the vegetable compartment 24 if the door 62 is opened and will not extend.

The mist atomizer 67 is located in one part of the first cooling channel 29 and is positioned near the gap between the lower container 64 and the upper container 65. A series of openings 71 for air flow are made on one part of the upper container 65.

Now, the operation and effects with respect to the refrigerator having the configuration as described above will be described. First, the operation of the freeze cycle will be described. The freezing cycle works, and the cooling operation is performed upon a signal from the lower control layer (level) (not shown) in accordance with the set temperature of the refrigerator. The coolant of high temperature and high pressure, released as a result of the action of the compressor 27, radiates heat and condenses, is brought into a liquid state in a condenser (not shown) and reaches a capillary tube (not shown). After that, the pressure is reduced in the capillary tube, and heat is exchanged with the suction tube (not shown) to the compressor 27 so that it turns into a liquid coolant of low temperature and low pressure, and reaches the evaporator 30. According to the action of the cooling fan 31, heat exchange is performed with air in each storage compartment, and the coolant in the evaporator 30 is dehydrated and evaporated, and cold low-temperature air performs predetermined cooling of each compartment, being adjustable in feed with a damper and the like. The coolant from the evaporator 30 passes through the suction tube and is drawn in by the compressor 27.

By heat exchange with air in each storage compartment, the formation of moisture becomes frost on the evaporator 30 during heat exchange with air in each storage compartment. A signal is periodically output from the lower control layer (not shown), thereby stopping the compressor 27 passing current to the radiation heater 32 and the defrosting evaporator 30.

Now will be described the movement of cold air in the refrigerator 1.

Cold air purged from the cooling fan 31 is purged in a distributed manner on the lower surface and the upper surface through the duct 91. The cold air distributed on the lower surface passes through the first outlet 47 for the freezer compartment and the second outlet 48 for the freezer compartment to be exhausted to the freezer compartment 25, exchanges heat with the air in the freezer compartment 25 and passes through the inlet 49 for the freezer compartment to return to the cooling compartment 28.

From the cold air blown from the cooling fan 31, cold air distributed to the top surface passes from the outlet 59 for the refrigerator compartment to the refrigerator compartment 21 through the duct 50 for the refrigerator compartment and the side of the refrigerator compartment corresponding to the double damper 39. Part of such cold air passes from the outlet 52 of the temperature-controlled compartment to the temperature-controlled compartment 22 through the duct 51 for the temperature-controlled compartment and side of the double shutter 39 temperature-controlled separation. At the same time, a signal is output from the lower control layer (not shown) to act as a double damper 39, to control the flow of cold air, to control the temperature of the refrigerator compartment 21 and switchable by the temperature of the compartment 22, and bring the temperature inside the refrigerator to a predetermined temperature.

The cold air blown into the refrigerator compartment 21 exchanges heat with the air in the refrigerator compartment 21, is drawn from the inlet 60 for the refrigerator compartment, and returns to the cooling compartment 28 through the return duct 61 for the refrigerator compartment, the return duct 57 for the refrigerator compartment and the duct 92 reverse feed for the refrigerator compartment. A portion of the returned cold air of the refrigerator compartment 21 enters the vegetable compartment 24 through the outlet for the vegetable compartment 45 located in the middle of the return duct 92 for the refrigerator compartment, passes between the lid 66 and the second partition 34 and enters the lower container 64 from the front of the upper container 65. Cold air, once entering the lower container 64, again passes the lower part of the lower container 64 from the front of the lower container 64, is drawn from the inlet 46 for vegetable compartment and is reduced to the return duct 92 for the refrigeration compartment. As is evident from the sequence of actions, the vegetable compartment 24 is cooled by using the return cold air of the refrigerator compartment 21.

Cold air, blown into the temperature-controlled compartment 22, exchanges heat with the air in the temperature-controlled compartment 22 and returns to the cooling compartment 28 through the return duct 55 for the temperature-switched compartment.

The lid 66 closes the hole on the upper side of the upper container 65 to prevent cold air from direct contact and dehydration of stored food. Typically, beverages, such as those in PET bottles, are often placed in the space in front and behind the lower container 64 and the upper container 65, where cold air is in direct contact with such a part, and a cooling rate is provided.

Moisture evaporates from food stored inside the lower container 64 over time from the moment it is placed inside. Air containing evaporated moisture enters the outer side of the container from the gap between the lower container 64 and the rear surface of the upper container 65 and reaches a mist atomizer 67 located close to the direction of movement of the portion of the cold air discharged from the outlet 45 for the vegetable compartment and passed into the lower container 64 through the upper space of the lid 66. The inner part of the atomizer 67 fog through the duct 91 is cooled to have a temperature below ambient, and moisture in the air con nsiruetsya atomizer 67 inside fog. Water condensate is sprayed in fog form from the gap between the lower container 64 and the upper container 65 into the interior of the container. Evaporated water from stored food is returned directly to the stored food by spray mist 67.

When placing the spray gun 67 fog near the gap of the lower container 64 and the upper container 65, high humidity cold air in the container can be collected and turned into a fine droplet microscopic fog (microfog) of high diffusivity and sprayed into the container from the vicinity of the gap between the lower container 64 and the upper container 65. The container Thus, it can be filled with small-dropping fog, which has high diffusivity and the effect of maintaining high freshness of vegetables.

The vegetable compartment 24 includes a mist atomizer 67, wherein cold air enters from outside the vegetable compartment 24 through the outlet for the vegetable compartment 45, which is the outlet for cold air, and cold air enters the outside of the vegetable compartment 24 through the inlet 46 for the vegetable compartment which is the cold air inlet. Thus, a path of movement of cold air is formed in the vegetable compartment 24, in which cold air mainly moves along the outside of the container located in the vegetable compartment 24 and exits to the outside of the vegetable compartment 24 through the inlet 46 for the vegetable compartment after passing from the inlet openings 46 for the vegetable compartment, and a spray mist 67 is performed on such a path of movement of cold air.

Further, in the present embodiment, the vegetable compartment outlet 45, which is a cold air outlet, is located on a side above the mist atomizer 67 in the storage compartment including the mist atomizer 67. The vegetable compartment inlet 46, which is the cold air inlet, is located on the side below the mist atomizer 67 and is positioned so that the vertical distance (up and down) from the vegetable outlet and the mist atomizer 67 is more than shorter than between the vegetable compartment inlet 46 and the mist atomizer 67. In other words, the mist atomizer 67 is located on the upper side close to the outlet for the vegetable compartment 45 in the vertical direction.

Thus, in the vegetable compartment 24, a mist atomizer 67 is disposed between the outlet for the vegetable compartment 45 and the inlet 46 for the vegetable compartment in the vertical direction. Cold air enters through a vegetable compartment outlet 45, which is a cold air outlet, from outside the vegetable compartment 24, and cold air exits to the outside of the vegetable compartment 24 through a vegetable compartment inlet 46, which is a cold air inlet. Thus, a path of movement of cold air is formed in the vegetable compartment 24, in which cold air mainly moves along the outside of the container located in the vegetable compartment 24 and exits to the outside of the vegetable compartment 24 through the inlet 46 for the vegetable compartment after passing from the inlet openings 46 for the vegetable compartment, and a spray mist 67 is located on such a path of movement of cold air.

The volume of cold air moving along the path of movement of cold air, in which cold air passing from the outlet 45 for the vegetable compartment to the storage compartment, moves outside the vegetable compartment 24 through the inlet 46 for the vegetable compartment, is large. Thus, the speed of movement of cold air becomes relatively high, and cold air from the container is drawn so that cold high humidity air seeps into the path of movement of cold air, whereby moisture leaving the container can be effectively collected and condensed in the atomizer 67 fog. Consequently, water condensate can be turned into microscopic fog, and microscopic fog of high diffusivity can be returned to the container, whereby the inside of the container can be sufficiently moistened with microscopic fog, and the freshness of vegetables can be preserved.

In the present embodiment, the outlet for the vegetable compartment 45, which is the outlet for cold air, is located on the side above the mist atomizer 67 in the vegetable compartment 24 incorporating the mist atomizer 67. The vegetable compartment inlet 46, which is the cold air inlet, is located on the side below the mist atomizer 67 and is located at a position in the vertical direction from the vegetable compartment outlet 45 and the mist atomizer 67 shorter than between the inlet 46 for vegetable compartment and a spray of 67 fog. In other words, the mist atomizer 67 is located on the upper side close to the outlet for the vegetable compartment 45 in the vertical direction.

The microscopic fog created in the mist atomizer 67 can move in a stream of large volume of cold air passing from the outlet for the vegetable compartment, when the mist atomizer 67 is placed on the side close to the outlet for the vegetable compartment 45, which is the cold air outlet, vertical direction. The inside of the container can be sufficiently moistened, and the freshness of the vegetables can be maintained as a result of containing a larger volume of microscopic fog in the cold air moving through the vegetable compartment 24. The mist sprayer 67 is located in the vertical direction on the back side of the vegetable compartment 24, where the flow is the largest in the path of movement of cold air, in which cold air mainly moves along the outer side of the container located in the vegetable compartment 24, and to the outer side in vegetable compartment 24 through inlet 46 for vegetable compartment after being entered from the inlet port 46 for vegetable compartment. Thus, the microscopic fog created by the mist spray 67 can move in a stream of large volume of cold air entering from the outlet for the vegetable compartment 45, and the inside of the container can be sufficiently moistened, and the freshness of the vegetables can be maintained as a result of containing a larger volume of microscopic fog in cold air moving through the vegetable compartment 24.

In the vegetable compartment 24, comprising a mist atomizer 67, the mist atomizer 67 is located on the center line 24a (see the corresponding part in FIG. 4) of the vegetable compartment 24 in the vertical direction or on the side above the middle line 24a in the vertical direction.

The microscopic fog created in the mist atomizer 67 from the upper side can move in a stream of cold air moving through the vegetable compartment 24, using the characteristic that cold air is moving to the lower surface. Therefore, the inside of the container can be sufficiently moistened, and the freshness of the vegetables can be maintained as a result of a larger volume of microscopic fog in the cold air moving through the vegetable compartment 24. The gap between the spray gun 67, the lower container 64 and the upper container 65 are not limited to those shown in FIG. relative vertical positions and may shift slightly. If the portion of the mist sprayer 67 is approximately as high as the gap between the lower container 64 and the upper container 65, then the air containing evaporated water from the stored food that exits to the outside of the container from the gap between the lower container 64 and the rear surface of the upper container 65 on the bottom surface by the movement of cold air on the rear surface of the container. Since the atomizer 67 fog is located in the path of movement of cold air, evaporated water can be effectively collected.

A portion of the cold air discharged from the outlet for the vegetable compartment 45 extends along the rear surface of the lower container 64 and the upper container 65 and is drawn in from the inlet 46 for the vegetable compartment. Air containing evaporated water from stored food products that exits to the outside of the container from the gap between the lower container 64 and the rear surface of the upper container 65 moves toward the lower surface by the movement of cold air along the rear surface of the container, and the evaporated water can be effectively collected since fog sprayer 67 is located in the path of movement of cold air.

The space for the mist sprayer 67, the lower container 64 and the upper container 65 is not limited to the relative vertical positions shown in FIG. 8 and may be slightly offset. Essentially, the same effects can be obtained as long as the part corresponding to the mist sprayer 67 has substantially the same height as the gap between the lower container 64 and the upper container 65.

The volume of the cold air stream that goes to the outside of the container is small and does not prevent fog spraying. Moisture, to the extent necessary for spraying the fog, may be supplied to the spray gun 67 fog. In addition, the cold air exiting onto the outside of the container is kept to a very small extent to the extent that it does not reduce the freshness of the food in the lower container 64.

In this case, the mist particles to be sprayed are from about 0.005 microns to about 20 microns and are very microscopic. The mist atomizer 67 can spray by converting water into fine particles by means of an ultrasonic signal, spray it by electrostatic spraying, or spray it by injection (using a pump).

Thus, the cycle “moisture release from food - condensation - spray mist” is repeated, where according to the present embodiment, food products whose cooling rate should be taken into account, such as in PET bottles, are cooled directly by the cold air discharged, and the freshness of the products Foods in which attention should be paid to “kinkiness,” such as greens, is maintained by spraying fog.

In this case, although not shown, the side wall of the inside of the vegetable compartment 24 is properly heated by a heater, etc. so that the mist particles scattered on the outside of the container and the evaporated water from the vegetables do not condense. The airflow hole 71 in the upper container 65 acts to prevent excessive condensation in the upper container 65.

The atomizer 67 fog can be locally cooled when setting the mounting of the atomizer 67 fog of the first cooling channel to a thinner wall than its periphery.

The second lower partition panel 36 acts as a cooling panel and cools the interior of the container. Since the second lower septum panel 36 is larger in configuration than the upper container 65 and there is no obstacle between the storage section of PET bottles and the like, beverages such as those in PET bottles can cool relatively quickly.

Therefore, in the present embodiment, moisture seeping from the gap between the upper container 65 and the lower container 64 is effectively collected and returned to the inside of the container by the fog sprayer 67 according to the location of the fog sprayer 67 in the container in the vicinity of the gap between the upper container 65 and the lower container 64 The inside of the container is thus sufficiently moistened and the freshness of the vegetables can be maintained.

In the present embodiment, since the mist atomizer 67 is located in the cooling channel provided in the storage compartment, moisture can be condensed and collected by cooling the mist atomizer 67 using the low temperature portion of the cooling channel.

According to the location of the fog atomizer 67 in one of the cold air movement paths between the cold air outlet and the cold air inlet, moisture in the storage compartment can be effectively collected and then returned to the container again by the fog atomizer 67, whereby the inside of the container can be sufficiently moistened. and the freshness of vegetables can be preserved.

In the present embodiment, a mist atomizer 67 is disposed between the cold air outlet and the cold air inlet in the cooling channel located in the storage compartment and including the cold air outlet and the cold air inlet. Moisture moving between the cold air outlet and the cold air inlet can be efficiently condensed and collected by cooling the mist atomizer 67 to a temperature lower than in the inside of the storage compartment using the cooling channel.

In the present embodiment, the moisture condenses more reliably and collects when the part of the mist atomizer is located at the same height with a gap for the upper container and the lower container.

In the present embodiment, an ultrasonic signal method is used for the mist spray device, and microscopic fog can be created having a particle diameter of several microns. Since a larger atomization volume can be satisfied, the inside of the container can be sufficiently humidified by microscopic fog, and the freshness of the vegetables can be maintained.

In the present embodiment, an electrostatic spray method can be used for the mist atomizer and microscopic mist can be created having a particle diameter of from a few nm to a few microns. Since the mist spray has a negative charge, the adhesion to vegetables and the like can be increased, and the freshness of vegetables can be maintained.

(Second Embodiment)

Figure 9 shows a longitudinal cross section of a refrigerator according to a second embodiment of the present invention. In Fig. 9, the basic configuration is similar to that of Fig. 1 and Fig. 8 described in the first embodiment. Identical components are identified by the same reference numerals. In the present embodiment, the upper container 65 of the vegetable compartment 24 does not have a lid 66.

Below will be described the operation and effects regarding the refrigerator having the configuration as described above. Cold air blown into the refrigerator compartment 21, which exchanges heat with the air in the refrigerator compartment 21, is drawn from the inlet for the refrigerator compartment 60 and returned to the cooling compartment 28 through the return duct 61 for the refrigerator compartment, the return duct 57 for the refrigerator compartment and the duct 92 reverse feed for the refrigerator compartment. Part of the returned cold air of the refrigerator compartment 21 passes into the vegetable compartment 24 through the outlet for the vegetable compartment 45 located in the middle of the return duct 92 for the refrigerator compartment, passes through the upper part of the upper container 65 and enters the lower container 64 from the front of the upper container 65 Cold air, once entering the lower container 64, again flows into the lower part of the lower container 64 from the front of the lower container 64, is drawn in from the inlet 46 for o the main compartment and is reduced to the return duct of the refrigeration compartment 92. As is evident from the sequence of operations, the vegetable compartment 24 is cooled by using the return cold air of the refrigeration compartment 21.

Cold air, blown into the temperature-controlled compartment 22, exchanges heat with the air in the temperature-controlled compartment 22 and returns to the cooling compartment 28 through the return duct 55 for the temperature-switched compartment.

Moisture evaporates from food stored inside the lower container 64 over time from the moment it is placed inside. In this case, the air containing the evaporated moisture is discharged from the outlet 45 for the vegetable compartment, leaves the outside of the container from the gap between the lower container 64 and the rear surface of the upper container 65 in the direction of movement of one part that has passed into the lower container 64 through the upper part of the upper container 65 and an airflow hole 71 formed in the upper container 65 and reaches a mist atomizer 67 located in the vicinity. The inner part of the mist atomizer 67 is cooled by the duct 91 so that it is lower than the ambient temperature so that moisture in the air condenses in the inner part of the mist atomizer 67. Water condensate is sprayed in the form of a mist into the interior of the container from the gap between the lower container 64 and the upper container 65. As a result, the evaporated water from the stored food is again returned by the atomizer 67 fog to the stored food directly.

A portion of the cold air discharged from the outlet for the vegetable compartment 45 passes through the lower container 64 and the rear surface of the upper container 65 and is drawn in from the inlet 46 for the vegetable compartment. Air containing evaporated water from stored food products that has passed to the outside of the container from the gap between the lower container 64 and the rear surface of the upper container 65, passes the lower side in the direction of cold air movement of the rear surface of the container, and the mist atomizer 67 effectively collects the evaporated water since it located in the path of movement of cold air.

Therefore, in the present embodiment, moisture leaked from the gap between the upper container and the lower container can be efficiently collected by the mist sprayer 67 according to the location of the mist sprayer 67 in the container near the gap between the upper container 65 and the lower container 64. It then returns to the container so that the inside of the container is sufficiently moistened, and the freshness of vegetables can be maintained.

Moisture in the storage compartment is more efficiently collected and returned to the container with the fog spray 67, so that the inside of the container is sufficiently moistened, and the freshness of vegetables can be maintained according to the location of the fog spray 67 in one of the cold air movement paths between the cold air outlet and the inlet cold air.

(Third Embodiment)

5 is a front view according to a third embodiment of the present invention, showing a state in which the door is detached. 10 shows a longitudinal cross section of a refrigerator according to a third embodiment of the present invention. In FIG. 5 and FIG. 10, the basic configuration is similar to that of FIG. 1 and FIG. 8 described in the first embodiment. Identical components are identified by the same reference numerals. The difference with the first embodiment is that the lower part of the mist atomizer 67 is on the side above the base surface of the upper container 65 in one part of the first cooling channel 29.

The operation and effects of the refrigerator having the configuration as described above will be described. Moisture evaporates from food stored inside the lower container 64 over time from the moment it is placed inside. In this case, the air containing the evaporated moisture exits to the outside of the container from the gap between the lower container 64 and the rear surface of the upper container 65 and reaches a mist atomizer 67 located nearby in the direction of movement of the part of the cold air discharged from the outlet 45 for the vegetable compartment and passed into the lower container 64 through the upper space of the lid 66. The inner part of the atomizer 67 fog through the duct 91 is cooled to be below ambient temperature, and in aha in the air condenses inside mist sprayer 67. Water condensate is sprayed in the space of the rear side of the upper container 65, but the mist particles naturally fall under their own weight and are scattered into the interior of the container from the gap between the lower container 64 and the upper container 65, positioned directly below the fog atomizer 67. As a result, the evaporated water from the stored food products through the atomizer 67 mist again returns to the stored food directly.

A portion of the cold air discharged from the outlet for the vegetable compartment 45 extends along the rear surface of the lower container 64 and the upper container 65 and is drawn in from the inlet 46 for the vegetable compartment. Air containing evaporated water from stored food products that exits to the outside of the container from the gap between the lower container 64 and the rear surface of the upper container 65 moves to the lower surface in the direction of movement of cold air on the rear surface of the container, and the evaporated water can be effectively collected since the atomizer 67 fog located in the path of cold air.

The inlet opening 46 for the vegetable compartment, designed to return cold air from the vegetable compartment 24 again to the return duct 92 for the refrigeration compartment, is located at a position at the bottom of the vegetable compartment 24 of the first cooling channel 29. The first outlet 47 for the freezer compartment and the second outlet the hole 48 for the freezer compartment for blowing cold air from the duct 91 to the freezer compartment 25 are located in positions corresponding to the freezer compartment 25 for the first oh cradle channel 29. The inlet 49 for the freezer compartment, designed to return cold air from the freezer compartment 25 to the evaporator 30, is located in the lower part of the first cooling channel 29.

A mist spray 67 is located in the vegetable compartment 24 between the outlet for the vegetable compartment 45 and the inlet 46 for the vegetable compartment in the vertical direction.

Thus, the mist sprayer 67 is located in the vegetable compartment 24, where cold air enters from the outside of the vegetable compartment 24 through the outlet for the vegetable compartment 45, which is the outlet of cold air, and cold air enters the outside of the vegetable compartment 24 through the inlet 46 for the vegetable compartments, which is an inlet of cold air, thereby forming a path of movement of cold air in the vegetable compartment 24. The spray mist 67 is located on the path of movement of the cold one air.

Further, in the present embodiment, the vegetable compartment outlet 45, which is a cold air outlet, is located on a side above the mist atomizer 67 in the storage compartment including the mist atomizer 67. The vegetable compartment inlet 46, which is a cold air inlet, is located on the side below the mist atomizer 67 and is located at a position that is in a vertical distance from the vegetable compartment outlet 45 and the mist atomizer 67 is shorter than the distance between the vegetable compartment inlet 46 and the mist atomizer 67. In other words, the mist atomizer 67 is located on the upper side close to the outlet for the vegetable compartment 45 in the vertical direction.

The mist sprayer 67 is located on the upper part above the midline 24a (see corresponding location in FIG. 4) of the vegetable compartment 24 in the vertical direction.

The mist spray 67 is preferably performed on the side of the inlet 46 for the vegetable compartment than the horizontal center line 24b horizontally (left and right) relative to the vegetable compartment 24.

Thus, the mist sprayer 67 is located in the vegetable compartment 24 between the outlet for the vegetable compartment 45 and the inlet 46 for the vegetable compartment in the vertical direction. Cold air enters through the outlet for the vegetable compartment 45, which is the outlet for cold air, from the outside of the vegetable compartment 24, and cold air enters the outside of the vegetable compartment 24 through the inlet 46 for the vegetable compartment, which is the cold air inlet, so that a path is formed movement of cold air in the vegetable compartment 24, and a mist spray 67 is located in the path of movement of cold air.

Since there is a large volume of cold air moving along the path of movement of cold air, in which cold air passing from the outlet 45 for the vegetable compartment to the storage compartments exits to the outside of the vegetable compartment 24 through the inlet 46 for the vegetable compartment, the speed of movement of the cold air becomes relatively high, and cold air from the container is drawn so that cold high humidity air passes along the path of movement of cold air. The moisture exiting the container can thereby be effectively collected and condensed in the mist atomizer 67, the water condensate can be turned into microscopic fog, and the high diffusivity microscopic fog can be returned to the container, whereby the inside of the container can be sufficiently moistened by microscopic fog, and the freshness of vegetables may be preserved.

In the present embodiment, the vegetable compartment outlet 45, which is the cold air outlet, is located on the side above the fog atomizer 67, and the vegetable compartment inlet 46, which is the cold air inlet, is located on the side below the fog atomizer 67 in the vegetable compartment 24 comprising an atomizer 67 fog. The distance in the vertical direction from the outlet 45 for the vegetable compartment and mist spray 67 is shorter than the distance between the inlet 46 for the vegetable compartment and mist spray 67. In other words, the mist atomizer 67 is located on the upper side close to the outlet for the vegetable compartment 45 in the vertical direction.

The microscopic fog created in the mist atomizer 67 can move in a stream of large volume of cold air passing from the outlet for the vegetable compartment 45, according to the location of the mist atomizer 67 on the side close to the outlet for the vegetable compartment 45, which is the cold air outlet, in the vertical direction. The inside of the container can be sufficiently moistened, and the freshness of the vegetables can be maintained as a result of containing a larger volume of microscopic fog in cold air moving through the vegetable compartment 24.

In the vegetable compartment 24, comprising a mist atomizer 67, a mist atomizer 67 is located on the center line 24a of the vegetable compartment 24 in the vertical direction or on the side above the middle line 24a in the vertical direction.

The microscopic fog created in the mist sprayer 67 from the upper side can move in a stream of cold air moving through the vegetable compartment 24, using the characteristics that the cold air moves to the lower surface, whereby the inside of the container can be sufficiently moistened and the freshness of vegetables can be maintained as a result of containing a larger volume of microscopic fog in cold air moving through the vegetable compartment 24.

A mist atomizer 67 is preferably performed on the side of the vegetable compartment inlet 46 than the horizontal line 24b of the vegetable compartment 24 in the horizontal direction.

Thus, the moisture contained in the cold air can be effectively collected and condensed by the mist atomizer 67 according to the location of the mist atomizer 67 on the side of the vegetable compartment inlet 46, where the moisture becomes higher in the horizontal direction. Therefore, the inside of the container can be sufficiently humidified by microscopic fog, and the freshness of vegetables can be maintained. The volume of cold air flow that goes to the outside of the container is small and does not prevent fog spraying. Moisture to the extent necessary to spray the mist can be supplied to the mist sprayer 67. In addition, the cold air exiting onto the outside of the container is held back to a very small amount that does not reduce the freshness of the food in the lower container 64.

(Fourth Embodiment)

11 shows a longitudinal cross section of a refrigerator according to a fourth embodiment of the present invention. 11, the main configuration is similar to that of FIG. 8 described in the first embodiment. Identical components are identified by the same reference numerals. The difference with the first embodiment is that the upper edge of the mist atomizer 67, located in one part of the first cooling channel 29, is on the side below the upper edge of the lower container 64.

The operation and effects of the refrigerator having the configuration as described above will be described. Moisture evaporates from food stored inside the lower container 64 over time from the moment it is placed inside. In this case, the air containing the evaporated moisture leaves the outside of the container from the gap of the lower container 64 and the rear surface of the upper container 65 in the direction of movement of the part of the cold air discharged from the outlet 45 for the vegetable compartment and passing into the lower container 64 through the upper space of the lid 66. In this case, a stream of cold air from the outlet for the vegetable compartment 45 to the inlet 46 for the vegetable compartment is also present in the space on the rear surface the container, and moisture that has passed to the outside of the container is also drawn into the inlet 46 for the vegetable compartment. As a result, the region from the gap between the upper container 65 and the lower container 64 to the vegetable compartment inlet 46 is maintained with relatively high humidity. The mist spray 67 is located in a region of relatively high humidity since the upper edge is on the side below the upper surface of the lower container 64.

The inner part of the atomizer 67 mist through the duct 91 is cooled to be below ambient temperature, and moisture in the air condenses inside the atomizer 67 fog. Even if moisture condensed inside the mist atomizer 67 is sprayed in the form of mist particles, mist mist particles are discharged from the vegetable compartment inlet 46 in a state of cold air circulating in the vegetable compartment 24. However, if the compressor 27 stops or closes the double side corresponding to the refrigeration compartment damper 39, the inside of the vegetable compartment 24 is in a state of natural convection, so that the sprayed mist particles circulate inside the vegetable compartment 24, a natural convection is maintained. As a result, the evaporated water from the stored food products is returned directly to the stored food products through the mist sprayer 67.

Thus, moisture seeping from the gap between the upper container 65 and the lower container 64 is effectively collected by the sprayer 67 and returned to the container so that the inside of the container can be sufficiently moistened and freshness of vegetables can be maintained according to the location of the fog sprayer 67 in the container in the vicinity the gap between the upper container and the lower container.

Moisture in the storage compartment can be efficiently collected and returned to the container by means of a mist spray 67, so that the inside of the container can be sufficiently moistened and freshness of vegetables can be maintained according to the location of the mist spray 67 on one of the cold air movement paths between the cold air outlet and the inlet cold air hole.

In the present embodiment, a mist atomizer 67 is disposed between the cold air outlet and the cold air inlet in the cooling channel located in the storage compartment and including the cold air outlet and the cold air inlet.

Moisture moving between the cold air outlet and the cold air inlet can be efficiently condensed and collected by cooling the mist atomizer 67 to a temperature lower than in the inside of the storage compartment using the cooling channel.

(Fifth Embodiment)

3 is a front view according to a fifth embodiment of the present invention, showing a state in which the door is detached. 12 is a longitudinal cross-sectional view of a refrigerator according to a fifth embodiment of the present invention. In FIG. 3 and FIG. 12, the basic configuration is similar to that of FIG. 1 and FIG. 8 described in the first embodiment. Identical components are identified by the same reference numerals. The difference with the first embodiment is the inclusion of ribs 68 of the direction of air flow. On Fig shows a perspective view from the front surface of the vegetable compartment in the fifth embodiment of the present invention.

The mist atomizer 67 is located in one part of the first cooling channel 29 and is positioned close to the gap between the lower container 64 and the upper container 65. An air flow direction fin 68 extending substantially horizontally in the vegetable compartment 24 is integrally formed with the first cooling channel 29 on the left and to the right of the spray mist 67. The airflow direction fin 68 is located on the side above the upper edge of the rear surface of the lower container 64 to divide into the upper and lower part the space between the upper container 65, the lower container 64 and the first cooling channel 29. In this case, the airflow directional fin 68 and the upper container 65 and the airflow direction rib 68 and the lower container 64 are provided with a size space so that there is no contact with each other when opening or closing the door in the forward and backward directions. In the present embodiment, the airflow direction rib 68 is located on the side above the upper edge of the rear surface of the lower container 64, but may be the same height as the lower container 64.

A recess 69, which is a cold air outlet, is located near the mist atomizer 67 in one part of the upper edge of the rear surface of the lower container 64 and is lower than the upper edge of the rear surface of the lower container 64. In addition, a recess 69, where the gap is between the upper container 65 and the lower the container 64 is the largest, runs in the lower container 64, and the recess 69 for the lower container 64 is located in a position facing the mist atomizer 67.

The position of the upper and lower and left and right sides of the recess 69 simply requires that the spray opening 70 of the mist sprayer 67 is not obscured by the rear surface of the lower container 64. The cold air exit section of the container is formed by the recess 69 and the base surface of the upper container 65. In one part the upper container 65 has several holes 71 for air flow.

Part of the cold air discharged from the outlet for the vegetable compartment 45 passes between the lid 66 and the second partition 34 and enters the front of the lower container 64 from the front of the upper container 65. Cold air also flows again between the lower part of the lower container 64 and the first partition 33 from the front of the lower container 64, is pulled from the inlet 46 for the vegetable compartment and is reduced to the return duct intended for the refrigerating compartment 92.

From the outlet 45 for the vegetable compartment, part of the cold air is discharged to the lower surface along the wall of the first cooling channel 29 and has an air flow direction changed by a rib 68 of the air flow direction, made integrally in the first cooling channel 29 and located to the left and right of the fog atomizer 67 so that cold air passes to a greater or lesser extent to the front side. As described above, the airflow direction rib 68 is positioned at the same height or higher than the upper edge of the rear surface of the lower container 64, and thus, cold air whose airflow direction is changed to the front side enters the lower container 64 from the gap between the base surface the upper container 65 and the upper edge of the rear surface of the lower container 64 and cools the stored food products inside.

Moisture evaporates from food stored inside the lower container 64 over time from the moment it is placed inside. In this case, the air containing the evaporated moisture exits onto the outside of the container from the cold air outlet formed by the recess 69 and the base surface of the upper container 65, and reaches a mist atomizer 67 located nearby in the direction of movement of the cold air passing into the lower container 64 The high humidity cold air in the lower container 64 thus extends to the outside of the lower container 64 with a recess 69 as a center, the volume being the largest in the recess 69 bottom container 64 or cold air outlet. The periphery of the atomizer 67 fog is, therefore, a medium (atmosphere) of high humidity. The inner part of the atomizer 67 mist through the duct 91 is cooled to be below ambient temperature, and moisture in the air condenses inside the atomizer 67 fog. Fog-shaped water condensate is sprayed from the cold air outlet formed by the recess 69 and the base surface of the upper container 65 into the interior of the container. Evaporated water from stored food is returned directly to the stored food by spray mist 67.

The volume of cold air moving along the path of movement of cold air, in which cold air passing from the outlet 45 for the vegetable compartment to the storage compartment, exits to the outside of the vegetable compartment 24 through the inlet 46 for the vegetable compartment is large, and thus , the speed of movement of cold air becomes relatively high, and cold air from the container is drawn, so that cold air of high humidity seeps into the path of movement of cold air with a recess of 69 n lower pole container 64 as the center. Since the mist atomizer 67 is located in the opposite position to the recess 69, high humidity cold air from the inside of the container can be effectively collected and condensed in the mist atomizer 67, whereby water condensate can be turned into microscopic fog and the high diffusivity microscopic fog can be returned into the container. Therefore, the inside of the container can be sufficiently humidified by microscopic fog, and the freshness of vegetables can be maintained.

Therefore, in the present embodiment, cold air from the cold air outlet is introduced into the container and exits to the outside of the container from an area adjacent to the mist atomizer 67 relative to the container. The moisture present in the container, which is delivered from the cold air inlet to the evaporator under normal conditions, can be collected and returned to the container efficiently by the spray gun 67, whereby the inside of the container is sufficiently moistened and the freshness of the vegetables can be maintained.

In addition, in the present embodiment, the cold air exit portion is located in the vicinity of the mist atomizer 67, whereby the vicinity of the mist atomizer 67 becomes highly damp due to moisture from the inside of the container, and moisture can condense and collect efficiently.

In the present embodiment, the configuration of the container is comprised of an upper container and a lower container, and a cold air exit portion is located between the upper container and the lower container. Moisture from the lower container, where vegetables with leaves, etc. are often stored and where the moisture release is significant, it is efficiently concentrated in the vicinity of the mist atomizer 67 to be easily collected by the mist atomizer 67.

In addition, in the present embodiment, the recess is located on the upper edge of the rear surface of the lower container. It is not necessary to form a hermetically accurate partition, and a simple geometry configuration can be specified for the cold air outlet. Thus, the vicinity of the mist atomizer 67 becomes highly moist due to moisture in the lower container, and moisture can be effectively collected by the mist atomizer 67.

In the vegetable compartment 24, a mist sprayer 67 is disposed between the outlet for the vegetable compartment 45 and the inlet 46 for the vegetable compartment in the vertical direction. Since cold air enters through the outlet for the vegetable compartment 45, which is the outlet for cold air, from the outside of the vegetable compartment 24, and since cold air exits on the outside of the vegetable compartment 24 through the inlet 46 for the vegetable compartment, which is the cold air inlet, cold air mainly moves on the outside of the container located in the vegetable compartment 24, and goes to the outside of the vegetable compartment 24 through the inlet 46 for the vegetable o separation after it has entered the vegetable compartment 24 from the inlet 46 for the vegetable compartment. A mist atomizer 67 is disposed in a cold air path connecting the vegetable outlet outlet 45 and the vegetable compartment inlet 46 with the shortest distance.

In addition, in the present embodiment, the outlet for the vegetable compartment 45, which is the outlet for cold air, is located on the side above the atomizer 67 fog in the storage compartment (vegetable compartment 24), which includes the atomizer 67 fog. The vegetable compartment inlet 46, which is a cold air inlet, is located on the side below the mist atomizer 67. The vertical distance (between) of the vegetable outlet and mist spray nozzle 45 is shorter than the distance between the vegetable compartment inlet 46 and mist spray 67. In other words, the mist atomizer 67 is located on the upper side close to the outlet for the vegetable compartment 45 in the vertical direction.

In addition, the mist sprayer 67 is located in the upper part above the midline 24a (see corresponding midline 24a of FIG. 4) of the vegetable compartment 24 in the vertical direction. Mist sprayer 67 creates fog using water condensate obtained by condensation of moisture in the surrounding air, and spray it in the space in the storage compartment (vegetable compartment 24). In the present embodiment, the mist atomizer 67 is cooled using an air duct 91 purged with cold air on the side of the rear surface of the mist atomizer 67.

A recess 69, which is the cold air outlet, where is the largest volume of cold air exiting from the inside of the lower container 64 to the outside of the lower container 64, is located in the vicinity of the mist atomizer 67 in one part of the upper edge of the rear surface of the lower container 64, and the recess 69 is performed below the upper edge of the rear surface of the lower container 64.

The cold air exit portion, where is the largest volume of cold air exiting from the inside of the lower container 64 to the outside of the lower container 64, is a recess 69 or position where the gap between the upper container 65 and the lower container 64 is the largest in the lower container 64, and the recess 69 of the lower container 64 is made in the position facing the mist atomizer 67.

It is required that the position of the upper and lower and left and right sides of the recess 69 is simply such that the spray opening 70 of the mist sprayer 67 is not obscured by the rear surface of the lower container 64.

The cold air exit portion of the container is the gap formed by the recess 69 and the base surface of the upper container 65, and this portion is the position where the volume of cold air exiting from the inside of the container 64 to the outside of the lower container 64 is the largest.

The mist atomizer 67 is a type that condenses moisture in the air and replenishes a volume of water, the inside of which is cooled below ambient temperature by means of the duct 91, so that moisture in the air condenses inside the atomizer 67 of the mist. Water condensate is sprayed in the form of a mist from the cold air outlet formed by the recess 69 and the base surface of the upper container 65 into the interior of the container. As a result, the evaporated water from the stored food products is returned directly to the stored food products through the mist sprayer 67.

The damper, positioned relative to the flow above the outlet for the vegetable compartment 45, is located on the duct, and if cold air does not enter inward from the outlet 45 for the vegetable compartment, such a shutter is closed. Typically, the shutter is not positioned relative to the flow below the vegetable compartment inlet 46, and thus, cold air in the vegetable compartment 24 exits the vegetable compartment inlet 46 to the outside of the vegetable compartment 24, although in a small volume. In this case, an influx of cold air is created from the inside of the container 64, which is the container, in the direction of the inlet 46 for the vegetable compartment.

Thus, even if cold air is not entering inwardly from the outlet for the vegetable compartment 45, high humidity cold air leaves the cold air exit portion where the volume of moving cold air is largest since the wall surface in the height direction of the lower container 64 has a lower position and represents the position where the largest gap is between the base surface of the upper container 65 and the upper edge of the rear surface of the lower container 64. Therefore, the peri eriya mist sprayer 67, located near the exit portion of the cold air, becomes high humidity environment, and the environment is realized in which the moisture in the air easily condenses in the interior of atomizer 67 mist.

In addition, in the present embodiment, the outlet for the vegetable compartment 45, which is the outlet for cold air, is located on the side above the sprayer 67 fog in the vegetable compartment 24, which includes a sprayer 67 fog. The vegetable compartment inlet 46, which is the cold air inlet, is located on the side below the mist atomizer 67 and is positioned such that the distance in the vertical direction from the vegetable compartment outlet 45 and the mist atomizer 67 is shorter than the distance between the inlet 46 for vegetable compartment and sprayer 67 fog. In other words, the mist sprayer 67 is located on the upper side close to the outlet for the vegetable compartment 45 in the vertical direction, and the mist spray 67 is located on the center line 24a of the vegetable compartment 24 in the vertical direction or on the side above the middle line 24a in the vertical direction .

The atomized mist particles are sprayed onto the cold air stream in the vegetable compartment 24 using the characteristics that the cold air is moving toward the bottom surface, and thus, diffusivity can be increased (accelerated) and the mist can be sprayed more efficiently.

The gap between the mist sprayer 67, the lower container 64 and the upper container 65 is not limited to the relative vertical positions shown in FIG. 12 and may be slightly offset. If the part of the mist sprayer 67 is approximately the same height as the gap between the lower container 64 and the upper container 65, air containing evaporated water from stored food products passing to the outside of the container from the gap between the lower container 64 and the rear surface of the upper container 65, can be collected efficiently, and such evaporated water can be sprayed again in the form of fog.

In the present embodiment, the flap is not located on the outlet side of the vegetable compartment inlet 46 or the outlet side where cold air in the vegetable compartment 24 exits and is in communication with the outlet side of the duct.

Thus, when the shutter is positioned upstream on the cold air duct of the vegetable compartment outlet 45, which directs the flow of cold air to the vegetable compartment 24 or the storage compartment including a spray device or a mist atomizer, i.e., when cold air is not enters from the outlet 45 for the vegetable compartment, a stream of cold air is formed from the inner vegetable compartment 24 to the inlet for 46 for the vegetable compartment, although in a small volume, even if cold air does not enter from the outlet for the vegetable compartment 45, since the outlet side of the duct communicates with the outlet side of the inlet 46 for the vegetable compartment or the exit side where the cold air of the vegetable compartment 24 exits. Therefore, even in this state, the cold air in the lower container 64 goes to the outside of the container from the cold air outlet to the vegetable compartment inlet 46 and reaches a mist atomizer 67 located near the cold outlet air. Therefore, the vicinity of the mist sprayer 67 becomes a high humidity environment, and an environment is realized in which condensation can be easily performed in the vicinity of the spray device.

In the present embodiment, air duct 91, purged with cold air on the rear surface side, is used as cooling means to cool the mist atomizer 67 to a dew point or lower. With cold air, which is lower than the temperature of the periphery of the fog generation section in the freezing cycle, as a cooling means, the fog atomizer 67 can be cooled using a simple configuration without organizing a special cooling means, and an atomization device or a fog atomizer can be arranged while saving resources and saving energy.

If cold air having a temperature below the periphery of the mist generation portion in the freezing cycle is a cooling medium, low-temperature cold air of an adjacent compartment separated by an insulated wall from the storage compartment containing the fog atomizer 67 is used, and the cooling means is not limited to the rear surface duct 91 and may be low temperature adjacent storage compartment and the like.

Therefore, in the present embodiment, cold air from the cold air outlet (vegetable outlet 45) is introduced into the container (lower container 64, upper container 65) and exits to the outside of the container (lower container 64, upper container 65) from an adjacent with a spray gun 67 fog area of the container (lower container 64, upper container 65). The moisture present in the container (lower container 64, upper container 65), which is delivered from the cold air inlet (vegetable compartment inlet 46) to the evaporator 30 under normal conditions, can be effectively collected and returned to the container (lower container 64, upper container 65) by means of a mist sprayer 67. Therefore, the inside of the container (lower container 64, upper container 65) can be sufficiently moistened, and the freshness of vegetables can be maintained.

In addition, in the present embodiment, the cold air exit portion where the volume of cold air that seeps from the inside of the container (mainly the lower container 64) is the largest, or the fog spraying space is located in the vicinity of the fog sprayer 67. The surroundings of the mist atomizer 67 thereby become highly moist due to moisture from the inside of the container (mainly the lower container 64), and moisture can condense and collect efficiently.

In the present embodiment, the configuration of the container is comprised of an upper container 65 and a lower container 64, and the cold air exit portion is located in the gap between the upper container 65 and the lower container 64 (the gap of the upper container 65 and the lower container 64 is the cold air exit portion). Moisture from the lower container 64, where vegetables with leaves, etc. are often stored and where moisture release is significant, it is efficiently concentrated in the vicinity of the mist atomizer 67 so as to be easily collected by the mist atomizer 67.

In addition, in the present embodiment, the recess 69 is located on the upper edge of the rear surface of the lower container 64, where it is not necessary to form an airtight, exact septum, and the cold air exit portion may have a simple geometry configuration. Thus, the vicinity of the mist atomizer 67 becomes highly moist due to moisture from the inside of the lower container 64, and moisture can be effectively collected by the mist atomizer 67.

In the present embodiment, the cold air outlet portion where the volume of cold air exiting the container (lower container 64, upper container 65) is largest has been described as a recess 69 formed on the wall surface of the container (lower container 64), but the portion the cold air outlet may be a blind hole formed in the container (lower container 64).

In the present embodiment, the recess 69 formed below the upper edge of the rear surface of the lower container 64 is a cold air outlet, where the volume of cold air exiting from the inside of the lower container 64 to the outside of the lower container 64 is the largest. However, even if the lowest position is provided in a container intended for another purpose, such a position will not be a cold air outlet unless it is a position where the volume of cold air exiting from the inside of the lower container 64 to the outside of the lower container 64 is the largest , and thus the position where the volume of cold air exiting from the inside of the lower container 64 to the outside of the lower container 64 is substantially the largest is the cold exit section of air.

The cold air exit portion where the largest volume of cold air exiting from the inside of the lower container 64 to the outside of the lower container 64 is the position where the gap between the upper container 65 and the lower container 64 is the largest in the lower container 64. However, when spraying fog toward the upper container 65, the gap between the upper container 65 and the wall surface in the upper part or the upper container 65 may be a cold air outlet. If there is a position where the largest volume of cold air leaving the inside of the container to the outside of the container is the largest, as a portion of the exit of cold air, regardless of the structural relationship in the present embodiment, the fog atomizer 67 is carried out in the vicinity thereof.

The airflow direction fin 68, which is a cold air injection means, is located on the side below the outlet 45 for the vegetable compartment, which is the cold air outlet. Using the characteristic that cold air moves to the bottom surface, a path of movement is formed in which high humidity cold air moving in a stream of a large volume of cold air passing from the vegetable compartment outlet 45 receives a direction changed by an air flow direction fin 68 on the lower surface, passes into the lower container 64, circulates in the lower container 64 and then goes to the outside of the lower container 64 in the form of high humidity cold air tee. Cold air is actively directed into the container and then circulated, and then the moisture present in the container can be transported to the vicinity of the mist atomizer 67, and thus, the inside of the lower container 64 can be sufficiently moistened by the mist atomizer 67, and the freshness of the vegetables can be maintained.

The present invention encompasses a rib 68 of the direction of air flow, which is a means of introducing cold air, performed on the side of the surface of the rear wall, on which the volume of moving cold air is significant in the path of movement of cold air, in which cold air passed into the vegetable compartment 24 from the outlet 45 for the vegetable compartment, which is the outlet of cold air, goes to the outside of the vegetable compartment 24 through the inlet 46 for the vegetable compartment, vlyayuscheesya inlet of cold air. Thus, cold air can be actively directed into the container and can be circulated, and then the moisture in the container can be transported to the vicinity of the mist atomizer 67, moisture can be collected by the mist atomizer 67, the inside of the container can be sufficiently moistened, and the freshness of the vegetables can be maintained.

The container includes an upper container 65 and a lower container 64, and an air flow guide rib 68, which is a cold air injection means, is located near the gap between the containers, so that cold air can be directed towards the lower container 64 and circulate, and then moisture in the lower container 64 can be efficiently assembled by a mist atomizer 67. The moisture is returned to the lower container 64 by means of a mist spray, so that the inside of the lower container 64 can be sufficiently moistened and the freshness of the vegetables can be maintained.

An airflow direction fin 68, which is a cold air injection means, is protruded from the wall surface in the vegetable compartment 24, so that cold air injection means for changing the direction of the cold air flow is provided, of a simple design, and cold air injection means can be provided, having a low number of failures and high reliability.

In addition, since the airflow direction rib 68 is located on the side above the top edge of the container on the side facing the airflow direction rib 68, characteristics that cold air moves to the lower surface can be used. A path can be formed in which high humidity cold air moving in a large volume of cold air passing from the vegetable compartment outlet 45, which is the cold air outlet, has a direction changed by a rib 68 of the air flow direction located on the lower side passes into the container and circulates in the container and then goes to the outside of the container in the form of high humidity cold air. Cold air is actively directed into the container and then circulated, and then the moisture present in the container can be transported to the vicinity of the mist atomizer 67, whereby moisture is collected and returned to the container by the mist atomizer 67, so that the inside of the container can be sufficiently moistened and the freshness of vegetables can be maintained .

As described in the present embodiment, the cold air introduction means is located on the side of the atomizer 67 of the mist. Cold air introduced into the container may circulate in the container, the moisture present in the container may be transported to the vicinity of the mist atomizer 67, and moisture may be collected and returned to the container by the mist atomizer 67. Thus, the inside of the container can be sufficiently moistened, and the freshness of vegetables can be maintained.

In the present embodiment, the configuration of the container is comprised of an upper container and a lower container, and the gap between the upper container and the lower container is widened in the vicinity of the mist atomizer 67. Moisture from the inside of the container can thus be effectively collected in the vicinity of the mist atomizer 67, condense, and collected by the mist atomizer 67.

In the present embodiment, in the cooling channel located in the storage compartment and including the cold air outlet and the cold air inlet, the configuration of the cold air introduction means constitutes an airflow direction fin 68 integrally formed with the cooling channel. The movement of cold air discharged from the cold air outlet is changed by the airflow directional edge so as to be easily inserted into the container.

The damper positioned relative to the flow above the outlet for the vegetable compartment 45 is located on the duct, and if the cold air is not coming in from the outlet 45 for the vegetable compartment, such a shutter is closed.

Typically, the shutter is not located downstream of the vegetable compartment inlet 46, and thus, cold air from the vegetable compartment 24 exits the vegetable compartment inlet 46 to the outside of the vegetable compartment 24, although in a small volume. In this case, a stream of cold air is created from the inside of the lower container 64, which is the container, towards the vegetable compartment inlet 46. However, in this case, also, the cold air passing from the lower container 64 has an air flow direction changed by the air flow direction rib 68, which is a means of introducing cold air, and collects near the fog atomizer 67 without being directed to the upper surface, and thereby moisture more easy to assemble with a 67 fog sprayer.

High humidity cold air leaves the cold air outlet where the largest volume of moving cold air is, since this is the position where the wall surface is the lowest in the direction of the height of the lower container 64, and the position where the gap is between the base surface of the upper container 65 and the upper the edge of the rear surface of the lower container 64 is the largest. The periphery of the mist atomizer 67 located close to such a cold air exit portion thus becomes a high humidity environment, and an environment is realized in which moisture in the air easily condenses in the interior of the mist atomizer 67.

Therefore, moisture from the lower container 64 can be transferred to the vicinity of the mist atomizer 67 by means of an airflow directional rib 68, which is a means of introducing cold air to the left and right of the mist atomizer 67. Moisture is collected and returned to the lower container 64 by means of a mist sprayer 67, whereby the inside of the lower container 64 can be sufficiently moistened and the freshness of the vegetables can be maintained.

In addition, since the airflow direction rib 68, which is the cold air injection means, is located on the side below the outlet 45 for the vegetable compartment, which is the cold air outlet, a characteristic can be used that the cold air moves to the lower surface. A path of movement is formed in which high humidity cold air moving in a large volume of cold air passed from the vegetable compartment outlet 45 has a direction changed by an air flow direction fin 68 located on the lower side, passes into the lower container 64 and circulates in the lower container 64 and then goes to the outside of the lower container 64 in the form of high humidity cold air. Cold air is actively directed into the container to cool the inside of the container, and then the moisture present in the container can be transported to the vicinity of the atomizer 67 fog. The inside of the lower container 64 can thus be sufficiently moistened with a mist spray 67, and the freshness of the vegetables can be maintained.

The present invention encompasses a rib 68 of the direction of air flow, which is a means of introducing cold air, performed on the side of the surface of the rear wall, on which there is a significant amount of moving cold air in the path of movement of cold air, in which cold air passed into the vegetable compartment 24 from the outlet 45 for the vegetable compartment, which is the outlet of cold air, goes to the outside of the vegetable compartment 24 through the inlet 46 for the vegetable compartment, vlyayuscheesya inlet of cold air. Thus, cold air can be actively directed into the container and circulated, and then the moisture present in the container can be transferred to the vicinity of the mist spray 67, moisture can be collected by the mist spray 67, the inside of the container can be sufficiently moistened, and the freshness of the vegetables can be maintained.

In this case, a heater, etc. (not shown) is located on the side below at least the rib 68 of the direction of air flow, which is a means of introducing cold air corresponding to the surface of the back wall inside the vegetable compartment 24, so that the surface of the back wall is properly heated, and fog particles scattered outside the container, and the evaporated water from vegetables does not condense.

Thus, an upward airflow is easily created on the surface of the rear wall equipped with an airflow directional edge 68, in comparison with the surfaces of the other walls, moreover, moisture easily rises upward on such an upward airflow, and moisture can be transported to the vicinity of the atomizer 67 of the fog without rising upwards rib 68 of the direction of air flow, which is a means of introducing cold air. Moisture is collected and returned to the container by a spray mist 67, so that the inside of the container can be sufficiently moistened and the freshness of the vegetables can be maintained.

Therefore, in the present embodiment, the airflow direction fin 68, which is used as the cold air injection means, is located on the side of the atomizer 67 of the mist. Cold air introduced into the container (lower container 64, upper container 65) can circulate in the container (lower container 64, upper container 65), and the moisture present in the container (lower container 64, upper container 65) can be transported to the vicinity of the atomizer 67 fog. Moisture can be collected and returned to the container (lower container 64, upper container 65) with a mist spray 67, so that the inside of the container (lower container 64, upper container 65) can be sufficiently moistened and the freshness of vegetables can be maintained.

In the present embodiment, the configuration of the container is comprised of an upper container 65 and a lower container 64, and the gap between the upper container 65 and the lower container 64 is widened in the vicinity of the mist atomizer 67. Moisture from the container (lower container 64, upper container 65) is effectively collected in the vicinity of the fog atomizer 67, and then the movement to the upper surface is stopped by the airflow direction rib 68, which is a means of introducing cold air, performed continuously left and right relative to the fog atomizer 67, so that moisture may collect towards the spray mist 67. In this way, moisture may condense and be collected by the mist atomizer 67.

In the present embodiment, in the first cooling channel 29 located in the storage compartment (vegetable compartment 24) and including a cold air outlet (outlet for the vegetable compartment 45) and a cold air inlet (inlet 46 for the vegetable compartment), the configuration of the introduction means of cold air constitutes a rib 68 of the air flow direction, made integrally with the first cooling channel 29. The movement of the flow of cold air discharged from the outlet is cold of air (outlet for vegetable compartment 45) is changed by an edge 68 of the air flow direction so as to easily be introduced into the container (the container bottom 64, upper container 65).

(Sixth Embodiment)

2 is a front view according to a sixth embodiment of the present invention, and is a view of a state in which the door is detached. 13 shows a longitudinal cross section of a refrigerator according to a sixth embodiment. In FIG. 2 and FIG. 13, the basic configuration is similar to that of FIG. 3 and FIG. 12 described in the fifth embodiment. Identical components are identified by the same reference numerals. The difference with the third embodiment is that the positions of the airflow direction rib 68 and the mist atomizer 67 are different. 16 is a perspective view of a vegetable compartment according to a sixth embodiment of the present invention.

The mist atomizer 67 is located in one part of the first cooling channel 29 and is positioned close to the gap between the lower container 64 and the upper container 65. The mist atomizer 67 is located in one part of the first cooling channel 29, with the upper edge 67a of the fog atomizer 67 being on the side below the upper edge 64a of the lower container 64. A recess 69, which is a cold air outlet, where the gap between the upper container 65 and the lower container 64 is greatest, is located in the lower container 64, and the recess 69 of the lower container 64 is disposed at a position facing to the nozzle 67 mist. The upper edge 64b of the lower container 64 at the position facing the mist spray 67 is positioned on the side above the spray opening 70 of the mist spray 67.

In addition, an airflow direction fin 68 extending substantially horizontally in the vegetable compartment 24 is integrally formed with a first cooling channel 29 on the left side of the mist sprayer 67. The airflow direction fin 68 is positioned on the side above the upper edge of the rear surface of the lower container 64 to divide into the upper and lower part the space between the upper container 65, the lower container 64 and the first cooling channel 29. In this case, the airflow directional fin 68 and the upper container 65 and the airflow direction rib 68 and the lower container 64 are provided with a size space so as not to come into contact with each other when opening or closing the door in the forward and backward directions. In the present embodiment, the airflow direction fin 68 is located on the side above the upper edge of the rear surface of the lower container 64, but may be at the same height as the lower container 64. In addition, in the present embodiment, the fog sprayer 67 is located on the right side, and the rib 68 air flow directions are made on the left side, but the positional ratios of the fog spray gun 67 and the air flow direction ribs 68 can be interchangeable. An airflow direction fin 68 is optionally located on both sides of the mist atomizer 67.

A recess 69 is located adjacent to the mist atomizer 67 in one part of the upper edge of the rear surface of the lower container 64 and is formed below the upper edge of the rear surface of the lower container 64. It is simply required that the position of the upper and lower and left and right sides of the recess 69 be such that the spray hole 70 the atomizer 67 of the fog was not hidden by the rear surface of the lower container 64.

The cold air exit portion of the container is formed by a recess 69 and a base surface of the upper container 65. In one part of the upper container 65, a plurality of air flow openings 71 are formed.

Moisture evaporates from food stored inside the lower container 64 over time from the moment it is placed inside. In this case, the air containing the evaporated moisture exits onto the outside of the container from the cold air outlet formed by the recess 69 and the base surface of the upper container 65, and reaches a mist atomizer 67 located nearby in the direction of movement of the cold air passing into the lower container 64 The inner part of the atomizer 67 mist through the duct 91 is cooled to be below ambient temperature, and moisture in the air condenses inside the atomizer 67 fog. Water condensate is sprayed in the form of a mist from the cold air outlet formed by the recess 69 and the base surface of the upper container 65 into the interior of the container. Evaporated water from the stored food is again returned via the atomizer 67 mist directly to the stored food.

Thus, the upper edge 64b of the lower container 64 in the position facing the mist spray 67 is positioned on the side above the spray hole 70 of the mist spray 67.

Thus, since the mist atomizer 67 is positioned in a part lower than the upper edge 64a of the lower container 64, the high humidity cold air present in the lower container is prevented from leaking from the upper edge 64a. The mist sprayer 67 is thus positioned in a high humidity atmosphere. In addition, the upper edge 64b of the lower container 64 in the position facing the mist spray 67 is positioned on the side above the spray hole 70 of the mist spray 67. The volume of cold air moving along the path of movement of cold air, in which cold air passing from the outlet 45 for the vegetable compartment to the storage compartment, exits to the outside of the vegetable compartment 24 through the inlet 46 for the vegetable compartment is large, and thus , the speed of movement of cold air becomes relatively high, and cold air from the container is drawn, so that cold air of high humidity seeps into the path of movement of cold air having a center glublenie 69 of the lower container 64. Because mist sprayer 67 located in opposite positions with respect to recess 69, the cold air of high humidity from the interior of the container can be efficiently collected and condensed in mist sprayer 67. Water condensate can be turned into microscopic fog, and microscopic fog of high diffusivity can be returned to the container, whereby the inside of the container can be sufficiently moistened with microscopic fog, and the freshness of vegetables can be preserved.

Therefore, in the present embodiment, cold air from the cold air outlet is introduced into the container and exits to the outside of the container from an area adjacent to the spray mist 67 of the container. The moisture present in the container, which is delivered from the cold air inlet to the evaporator under normal conditions, can be effectively collected and returned to the container with a mist spray 67, whereby the inside of the container is sufficiently moistened and the freshness of the vegetables can be maintained.

In addition, in the present embodiment, the cold air exit portion is located in the vicinity of the mist atomizer 67, whereby the vicinity of the mist atomizer 67 becomes highly damp due to moisture from the inside of the container, and moisture can condense and collect efficiently.

In the present embodiment, the configuration of the container is comprised of an upper container and a lower container, and a cold air exit portion is located between the upper container and the lower container. Moisture from the lower container, where vegetables with leaves, etc. are often stored and where the moisture release is significant, it is efficiently concentrated in the vicinity of the mist atomizer 67 so as to be easily collected by the mist atomizer 67.

In addition, in the present embodiment, the recess is located on the upper edge of the rear surface of the lower container. The formation of a hermetically accurate partition is not required, and the cold air outlet may be configured with a simple geometry. Thus, the vicinity of the mist atomizer 67 becomes highly moist due to moisture in the lower container, and moisture can be effectively collected by the mist atomizer 67.

A mist sprayer 67 is preferably performed on the side of the inlet 46 for the vegetable compartment than on the middle line 24b in the horizontal direction relative to the vegetable compartment 24. The middle line 24b in the horizontal direction is shown in the front view of FIG. Since the mist atomizer 67 is located on the side of the vegetable compartment inlet 46, where the moisture is higher left and right, moisture contained in the cold air can be effectively collected and condensed by the mist atomizer 67. Therefore, the inside of the container can be sufficiently humidified by microscopic fog, and the freshness of vegetables can be maintained.

In particular, if the damper positioned on the cold air duct upstream of the outlet 45 for the vegetable compartment is closed to allow cold air to enter the vegetable compartment 24, which is a storage compartment including a mist atomizer 67, that is, if cold air does not enter from the outlet 45 for the vegetable compartment, creates a stream of cold air from the vegetable compartment 24 to the inlet 46 for the vegetable compartment, although in a small volume, even if cold air does not enter from the outlet The opening for the vegetable compartment 45, since the outlet side of the inlet 46 for the vegetable compartment or the outlet side to which the cold air of the vegetable compartment 24 exits is in communication with the outlet side of the duct. In this state, also, the side of the vegetable compartment inlet 46 is in an atmosphere of higher humidity than the left and right center line 24b relative to the vegetable compartment 24, and an environment is obtained in which condensation can more easily be performed near the atomizing device or the mist atomizer . Since the mist spray 67 is preferably performed on the side of the vegetable compartment inlet 46 than on the left and right center line 24b relative to the vegetable compartment 24, moisture contained in the cold air can be effectively collected and condensed by the mist spray 67, whereby the inside The container can be sufficiently moistened with microscopic fog, and the freshness of vegetables can be maintained.

Therefore, in the present embodiment, cold air from the cold air outlet (outlet for vegetable compartment) is introduced into the container (lower container 64, upper container 65) and exits to the outside of the container (lower container 64, upper container 65) from an adjacent with a spray gun 67 fog area of the container (lower container 64, upper container 65). The moisture present in the container (lower container 64, upper container 65), which is delivered from the cold air inlet (vegetable compartment inlet 46) to the evaporator 30 under normal conditions, can be effectively collected and returned to the container (lower container 64, upper container 65) spray 67 fog. Therefore, the inside of the container (lower container 64, upper container 65) can be sufficiently moistened, and freshness of vegetables can be maintained.

In addition, in the present embodiment, the cold air outlet portion of the container (lower container 64, upper container 65) is located in the vicinity of the fog atomizer 67, so that the vicinity of the fog atomizer 67 becomes highly moist due to moisture from the inside of the container (mainly the lower container 64), and moisture can condense and collect efficiently.

In the present embodiment, the configuration of the container is comprised of an upper container 65 and a lower container 64, and the cold air exit portion is located in the gap between the upper container 65 and the lower container 64 (the gap of the upper container 65 and the lower container 64 is the cold air exit portion). Moisture from the lower container 64, where vegetables with leaves, etc. are often stored and where the moisture release is significant, it is efficiently concentrated in the vicinity of the mist atomizer 67 so as to be easily collected by the atomizer 67 fog.

In addition, in the present embodiment, the recess 69 is located on the upper edge of the rear surface of the lower container 64, where it is not necessary to form an airtight, exact septum, and the cold air exit portion may have a simple geometry configuration. Thus, the vicinity of the mist atomizer 67 becomes highly wet due to moisture from the inside of the lower container 64, and moisture can be effectively collected by the mist atomizer 67.

Since the airflow direction fin 68 is continuous to the left and right of the mist atomizer 67, cold air passing through the lower container 64 does not leak from the mist atomizer 67 left and right due to the airflow direction fin 68. Thus, the periphery of the mist sprayer 67 becomes highly humid and moisture can be effectively collected by the mist sprayer 67, the microscopic microdiffusivity fog being returned to the lower container 64, thus sufficiently moisturizing the inside of the lower container 64 and preserves the freshness of the vegetables.

In addition, since the airflow direction rib 68 is located on the side above the upper edge of the container on the side facing the airflow direction rib 68, a characteristic that cold air moves to the lower surface can be used. A path of movement can be created in which high humidity cold air moving in a large volume of cold air passed from the outlet for the vegetable compartment 45, which is the outlet for cold air, has a direction changed by an airflow direction fin 68 made on the lower side that passes into the container, circulates in the container and then goes to the outside of the container in the form of high humidity cold air. Cold air is actively directed into the container and then circulated, and then the moisture present in the container can be transported to the vicinity of the mist atomizer 67, whereby moisture is collected and returned to the container by the mist atomizer 67. The inside of the container can be sufficiently moistened and the freshness of the vegetables can be maintained.

As described in the present embodiment, the airflow direction fin 68, which is a means of introducing cold air, is continuous on the side of the atomizer 67 of the mist. Cold air introduced into the container (lower container 64, upper container 65) is circulated in the container (lower container 64, upper container 65), and the moisture present in the container (lower container 64, upper container 65) can be transported to the vicinity of the atomizer 67 fog . Moisture can be collected and returned to the container (lower container 64, upper container 65) with a mist spray 67, so that the inside of the container (lower container 64, upper container 65) can be sufficiently moistened and the freshness of vegetables can be maintained.

In the present embodiment, the configuration of the container is comprised of an upper container 65 and a lower container 64, and the gap between the upper container 65 and the lower container 64 is widened in the vicinity of the mist atomizer 67. Moisture from the inside of the container (lower container 64, upper container 65) can thus be effectively collected in the vicinity of the mist atomizer 67, condense, and collected by the mist atomizer 67.

In the present embodiment, in a first cooling channel 29 formed in the storage compartment (vegetable compartment 24) and including a cold air outlet (outlet for the vegetable compartment 45) and a cold air inlet (inlet 46 for the vegetable compartment), cold introduction means the air has the configuration of the ribs 68 of the direction of the air flow, made as a whole with the first cooling channel 29. The direction of the air flow of cold air leaving the container (bottom eynera 64, upper container 65), rib 68 changes air flow direction so that the cold air of high humidity easily introduced into the neighborhood of the atomizer 67 mist.

(Seventh Embodiment)

6 is a front view according to a seventh embodiment of the present invention, showing a state in which the door is detached. On Fig shows a longitudinal cross section of a refrigerator according to a seventh embodiment of the present invention. In FIG. 6 and FIG. 14, the basic configuration is similar to that of FIG. 1 and FIG. 8 described in the first embodiment. Identical components are identified by the same reference numerals. The difference with the first embodiment is the inclusion of an auxiliary air flow direction fin 168. 17 is a perspective view of a vegetable compartment in a seventh embodiment of the present invention.

The mist spray 67 is located in one part of the first cooling channel 29 and is positioned close to the gap between the lower container 64 and the upper container 65. An airflow direction fin 68, which is a moisture introducing element, extends substantially horizontally to the left and right of the mist spray 67 on the side of the surface of the rear wall of the vegetable compartment 24, corresponding to the first cooling channel 29. The rib 68 of the air flow direction is a moisture introduction element, positioned at the same height as the upper edge of the rear surface of the lower container 64 or positioned on the side above the upper edge of the rear surface of the lower container 64, and it divides the space between the upper container 65, the lower container 64 and the first cooling channel 29 into upper and lower parts. The secondary airflow direction fin 168, which acts as a moisture collection member, is located on the side below the airflow directional rib 68 on (adjacent to) the first cooling channel 29. The secondary airflow directional rib 168, which is the moisture collection unit, is continuous the slope is either left or right in a position on the side above the inlet 46 for the vegetable compartment and divides the space between the lower container 64 and the first cooling channel 29 into upper and lower part. The airflow direction fin 68 and the secondary airflow direction fin 168 and the upper container 65 and lower container 64 are provided with a size space so that they do not touch each other when opening or closing the door in the forward and backward directions.

Therefore, an auxiliary rib of the airflow direction 168, which is a moisture collection element, is located on the lower side of the surface of the rear wall or wall surface equipped with a spray gun 67 of fog, and the rib 68 of the airflow direction, which is a moisture introduction element, is located in the direction to the left and right of the spray 67 fogs. A mist atomizer 67 is located in a surface area of the rear wall surrounded by an airflow directional rib 68 and an auxiliary airflow directional rib 168. The airflow direction fin 68 and the secondary airflow direction fin 168 are formed integrally with the first cooling channel 29 or the surface side of the back wall of the vegetable compartment 24.

In the present embodiment, the airflow direction rib 68 is positioned on a side above the upper edge of the rear surface of the lower container 64, but may be at the same height as the lower container 64.

A recess 69 is located near the mist spray 67 on one part of the upper edge of the rear surface of the lower container 64 and is made lower than the upper edge of the rear surface of the lower container 64. The position of the upper and lower and left and right sides of the recess 69 should simply be such that the spray hole 70 of the spray 67 the fog was not obscured by the rear surface of the lower container 64. The cold air exit section of the container is formed by a recess 69 and a base surface of the upper container 65.

Part of the cold air entering the vegetable compartment 24 from the outlet for the vegetable compartment 45 is discharged to the lower surface along the wall of the first cooling channel 29 due to the characteristics that the cold air moves to the lower surface. After that, the airflow direction is changed by the airflow direction rib 68, made integrally with the first cooling channel 29 and located to the left and right of the fog atomizer 67, and the cold air moves to a greater or lesser extent towards the front side and does not move to the lower surface . Since the airflow direction rib 68 is positioned at the same height or higher than the upper edge of the rear surface of the lower container 64, as described above, cold air whose airflow direction is changed to the front side enters the lower container 64 from the gap between the base surface of the upper container 65 and the upper edge of the rear surface of the lower container 64 and cools the stored products inside. However, this flow is one part, and the cooling of the stored products inside is carried out mainly from the portion passing between the lid 66 and the second partition 34 and entering the front of the lower container 64 from the front or door 62 of the upper container 65.

If cold air from the outlet 45 for the vegetable compartment does not enter the vegetable compartment 24, moisture evaporates from food stored inside the lower container 64 over time from the moment it is placed inside. In this case, the air containing the evaporated moisture exits onto the outside of the container from the cold air outlet formed by the recess 69 and the base surface of the upper container 65, in the direction of movement of the cold air entering the lower container 64. This air has an air flow direction changed an airflow direction fin 68, which is an element for introducing moisture, which is continuous in the left and right directions from the atomizer 67 of the fog, and reaches the vicinity of the atomizer 67 of the fog. The inside of the atomizer 67 fog is cooled to be below ambient temperature by heat exchange from the duct 91 adjacent another compartment, and moisture in the air condenses inside the atomizer 67 fog. Water condensate is sprayed in the form of a mist from the cold air outlet formed by the recess 69 and the base surface of the upper container 65 into the interior of the container. As a result, the evaporated water from the stored food is again returned via the atomizer 67 mist directly to the stored food. Therefore, it is required that the cooling duct duct 91 for cooling the mist atomizer 67 is a space through which the cold air of the temperature zone moves lower than the storage compartment containing the mist atomizer 67. The cooling means can thus use the cold air of the adjacent storage compartment corresponding to the low temperature zone (for example, the freezing temperature zone) if duct 91 is not used.

When cold air does not enter from the outlet for the vegetable compartment 45, the shutter is usually not located relative to the flow below the inlet 46 for the vegetable compartment, even if the shutter installed relative to the flow above the outlet 45 for the vegetable compartment is closed. In this way, a stream of cold air is generated from the inside of the container 64 or container towards the vegetable compartment inlet 46, although in a small volume. Since the auxiliary airflow direction fin 168 is located on the side above the vegetable compartment inlet 46, the air containing the evaporated moisture does not move directly to the vegetable compartment inlet 46, but is held in the space formed by the airflow directional rib 68 and the auxiliary rib 168 air flow directions. Thus, high humidity cold air is stored in the space formed by the airflow direction fin 68 and the secondary air flow direction fin 168, and collects in the vicinity of the mist atomizer 67, whereby moisture can be easily collected by the mist atomizer 67.

Since the position of the mist sprayer 67 is the region where the wall surface in the height direction of the lower container 64 is the smallest and the place where the gap between the base surface of the upper container 65 and the upper edge of the rear surface of the lower container 64 is largest, high humidity cold air exits the exit section cold air, where the volume of moving cold air is the largest. Therefore, the periphery of the fog atomizer 67 located near such a cold air exit portion becomes a high humidity environment, and an environment is realized in which moisture in the air easily condenses in the interior of the atomizer 67 of the fog.

Consequently, moisture from the lower container 64 can be transferred to the vicinity of the mist atomizer 67 by means of an airflow direction rib 68, which is a moisture introduction element located to the left and right of the mist atomizer 67. In addition, particles of fog falling onto the bottom surface, not being sprayed into the container, from the fog sprayed from the spray gun 67 fog, can be collected by an auxiliary rib 168 directing the air flow, which is an element of moisture collection, performed continuously left and right below the spray gun 67 fog, and evaporate into the air from a position on the auxiliary rib 168 of the direction of air flow. Thus, moisture is collected and returned to the lower container 64 by means of a mist sprayer 67, and the inside of the lower container 64 can be sufficiently moistened and the freshness of the vegetables can be maintained. When mist particles that have fallen onto the bottom surface from the mist atomizer 67 are vaporized by an auxiliary airflow direction fin 168, which is an element for collecting moisture, moisture condensation that occurs when water droplets of mist accumulate on the base surface of the vegetable compartment can be prevented.

Since the auxiliary ridge of the air flow direction 168, which is the element of moisture collection, is made in the form of a slant in the direction to the right and left, even if a water drop falls on the auxiliary ridge 168 of the direction of air flow, water droplets can evaporate when moving down the slope towards the bottom surface whereby water droplets accumulating on the auxiliary rib of the air flow direction can evaporate more reliably.

In the present embodiment, the cold air flow on the rear surface side connecting the vegetable compartment outlet 45 located on the rear surface side of the storage compartment and the vegetable compartment inlet 46 with the shortest distance is enclosed by a double rib from the airflow directional rib 68 and the auxiliary rib 168 airflow directions. Thus, it is prevented that the largest portion of the dry cold air of relatively low temperature entering inside from the outlet for the vegetable compartment 45 moves to the bottom surface and exits the inlet 46 for the vegetable compartment and moves from the upper side to the front side on the side the rear surface and in the direction changed by the door 62 located on the side of the front surface, so that cold and dry cold air is introduced from the area entering the front of the lower end container 64. Consequently, beverages such as those in PET bottles stored on the front of the lower container 64 can be cooled with cold, dry cold air, and relatively high humidity cold air, after passing through the lower container 64, moves to the vicinity of the upper container 65 and the atomizer 67 fog. Thus, the humidity on the back side can become relatively higher than on the proximal side, that is, the side of the vegetable compartment door 62. Therefore, the periphery of the fog atomizer 67 located on the rear surface side becomes a high humidity environment, and an environment is realized in which moisture in the air easily condenses in the interior of the atomizer 67 of the fog.

In addition, the return duct 92 for the refrigerator compartment communicating with the inlet 46 for the vegetable compartment on the outlet side where the cold air of the vegetable compartment exits is usually combined with the cold air duct on the outlet side of another storage compartment, where through the duct on the outlet side the storage compartment of the temperature zone of freezing always moves a larger volume of cold air of low temperature than through the duct on the output side of the storage compartment of the temperature zone They are cooling, and thus the speed of movement is high in this place. The cold air of the storage compartment of the temperature cooling zone, such as the vegetable compartment of the present embodiment, is thus thus sometimes pulled (raised). However, since the cold air flow on the rear surface side is physically shielded by a double rib from the air flow direction rib 68 and the secondary air flow direction rib 168, which are ribs, as in the present embodiment, a decrease in humidity is prevented because the cold air on the back surface side is drawn out from the inlet 46 for the vegetable compartment. In other words, even if the inlet 46 for the vegetable compartment or the outlet side, where the cold air of the vegetable compartment exits, is reduced to the duct on the outlet side of the storage compartment for the freezing temperature zone with a lower temperature than in the vegetable compartment, a large volume of cold air positioned on the side above the auxiliary rib 168 of the direction of air flow on the side of the rear surface of the vegetable compartment, from the inlet 46 for the vegetable compartment, and olodny air, positioned on the upper edge 168 of the auxiliary air flow direction can be maintained with high humidity. Therefore, the periphery of the fog atomizer 67 located on the rear surface side becomes a high humidity environment, and an environment is realized in which moisture in the air easily condenses in the interior of the atomizer 67 of the fog.

Since the airflow direction fin 68, which is the moisture injection element, can carry the moisture in the container to the vicinity of the mist spray 67, the inside of the lower container 64 can be sufficiently moistened by the mist spray 67 and the freshness of the vegetables can be maintained.

The container includes an upper container 65 and a lower container 64, and an airflow guide rib 68, which is a moisture introducing element, is located near the gap between the containers, so that moisture from the lower container 64 can be effectively collected by the fog atomizer 67. The moisture is returned to the lower container 64 by the mist spray device, so that the inside of the lower container 64 can be sufficiently moistened and the freshness of the vegetables can be maintained.

The airflow direction fin, which is an element of introducing moisture, and the auxiliary airflow direction fin 168, which is an element of moisture collection, are made protruding from the wall surface in the vegetable compartment 24, so that the airflow direction of the cold air can be changed using a simple design, and the periphery of the atomizer 67 fog becomes a high humidity environment with a physical design with a low failure rate and high reliability.

In this case, a heater, etc. (not shown) is located on the side below at least the airflow direction rib 68, which is a moisture introducing element, on the surface of the back wall inside the vegetable compartment 24, and preferably on the side below the auxiliary airflow direction fin 168, which is a moisture collection element. The surface of the back wall is thus properly heated, and the mist particles scattered on the outside of the container and the evaporated water from the vegetables do not condense.

In particular, even if mist particles falling onto the bottom surface from the mist atomizer 67 are held by an auxiliary airflow direction rib 168, which is an element for collecting moisture, and become water droplets, the water droplets evaporate by what is located on the surface of the rear wall, whereby condensation due to water droplets of mist accumulating on the surface of the base of the vegetable compartment is prevented. At the same time, high humidity air can move towards the mist atomizer 67 located on the upper side closer to the secondary ridge of the air flow direction 168, the periphery of the mist atomizer 67 becomes a high humidity environment, and an environment in which moisture in the air condenses readily into atomizer 67 fog.

Thus, upward airflow is easily created on the surface of the back wall in comparison with other wall surfaces, and moisture can easily rise upward in such an upward airflow, and moisture can be transported to the vicinity of the mist sprayer 67 without rising upward through the airflow direction fin 68, which is an element of the introduction of moisture. Moisture is collected and returned to the container by a spray mist 67, so that the inside of the container can be sufficiently moistened and the freshness of the vegetables can be maintained.

Therefore, in the present embodiment, the airflow direction fin 68, which is used as the moisture introducing element, is located on the side of the atomizer 67 of the mist. Cold air introduced into the container (lower container 64, upper container 65) can circulate in the container (lower container 64, upper container 65), and the moisture present in the container (lower container 64, upper container 65) can be transported to the vicinity of the atomizer 67 fog. Moisture can be collected and returned to the container (lower container 64, upper container 65) with a mist spray 67, so that the inside of the container (lower container 64, upper container 65) can be sufficiently moistened and the freshness of vegetables can be maintained.

In the present embodiment, the configuration of the container is comprised of an upper container 65 and a lower container 64, and the gap between the upper container 65 and the lower container 64 is widened in the vicinity of the mist atomizer 67. Moisture from the container (lower container 64, upper container 65) is effectively collected in the vicinity of the mist atomizer 67, and then the movement to the upper surface is stopped by the airflow direction rib 68, which is a moisture introducing element that is continuous in the left and right directions from the mist atomizer 67, so that moisture can collect towards the mist atomizer 67, and moisture can condense and be collected by the mist atomizer 67.

In the present embodiment, in the first cooling channel 29 located in the storage compartment (vegetable compartment 24) and including a cold air outlet (outlet for the vegetable compartment 45) and a cold air inlet (inlet 46 for the vegetable compartment), a moisture introduction member has the configuration of the ribs 68 of the direction of air flow and the auxiliary ribs 168 of the direction of air flow, made integrally with the first cooling channel 29. The flow of cold air on the rear side the surface of the cold air discharged from the cold air outlet (outlet 45 for the vegetable compartment) is enclosed by a double rib or rib 68 of the air flow direction and an auxiliary rib 168 of the air flow direction, and thus prevents the passage of most of the dry cold air of relatively low temperature entering from the outlet 45 for the vegetable compartment, and its release from the inlet 46 for the vegetable compartment. The space between the airflow directional rib 68 and the secondary airflow directional rib 168 can be held with high humidity. The periphery of the mist atomizer 67 becomes a high humidity environment, and an environment is realized in which moisture in the air readily condenses in the interior of the atomizer 67 of the mist.

(Eighth Embodiment)

7 is a front view according to an eighth embodiment of the present invention, showing a state in which the door is detached. FIG. 18 is a perspective view of a vegetable compartment according to an eighth embodiment of the present invention. In FIG. 7 and FIG. 18, the basic configuration is similar to that of FIG. 6 and FIG. 17 described in the seventh embodiment. Identical components are identified by the same reference numerals. The difference with the seventh embodiment lies in the location and geometry of the mist atomizer 67 and the airflow direction rib 68.

The mist spray 67 is located in one part of the first cooling channel 29 and is positioned close to the gap between the lower container 64 and the upper container 65. The airflow direction fin 68, which is a moisture injection element, extends substantially horizontally to the left and right of the mist spray 67 on the surface of the rear wall of the side of the vegetable compartment 24, corresponding to the first cooling channel 29. The rib 68 of the air flow direction is an element of the introduction of moisture, positioned m at the same height with the upper edge of the rear surface of the lower container 64 or positioned on the side above the upper edge of the rear surface of the lower container 64 and divides the space between the upper container 65, lower container 64 and the first cooling channel 29 on the upper and lower part. The secondary airflow direction fin 168, which acts as a moisture collection element, is provided on the side below the airflow directional rib 68 on the first cooling channel 29. The secondary airflow directional rib 168, which is the moisture collection element, is continuous in the form of a slope or to the left, or to the right in the position on the side above the vegetable compartment inlet 46 and divides the space between the lower container 64 and the first cooling channel 29 into upper and lower parts. The airflow direction fin 68 and the secondary airflow direction fin 168 and the upper container 65 and the lower container 64 are provided with a size space so as not to come into contact with each other when opening or closing the door in the forward and backward directions.

In the present embodiment, the airflow direction rib 68 is located on the side above the upper edge of the rear surface of the lower container 64, but may be at the same height as the lower container 64. In the present embodiment, the mist sprayer 67 is located on the right side of the vegetable compartment 24, and the rib 68 air flow directions are located on the left side of the fog atomizer 67, but left and right can be interchanged.

Therefore, the auxiliary airflow direction fin 168, which is a moisture collection element, is performed on the side below the surface of the rear wall or the wall surface equipped with the mist spray 67, so as to be inclined to the left and right, and the airflow direction fin 68, which is an element the introduction of moisture, is located in the direction to the left and to the right of the atomizer 67 fog. A mist atomizer 67 is located in a space on the surface of the rear wall supporting high humidity, surrounded by an airflow direction rib 68 and an auxiliary airflow direction rib 168.

The secondary ridge of the air stream 168 is inclined to the left and right, and the end positioned on the higher side is the side equipped with a fog spray 67. The airflow direction fin 68 and the secondary airflow direction fin 168 are formed integrally with the first cooling channel 29 or the surface side of the back wall of the vegetable compartment 24.

Since the airflow direction rib 68 is continuous to the left and right of the mist atomizer 67, cold air from the lower container 64 does not leak out to the left and right of the mist atomizer 67, the periphery of the mist atomizer 67 becomes highly humid, and moisture can be effectively collected by the atomizer 67 fogs. The inner part of the lower container 64 can be sufficiently moistened, and the freshness of the vegetables can be preserved by returning the microscopic diffusivity fog to the lower container 64 again.

In addition, particles of fog falling onto the lower surface without being sprayed into the container from the fog sprayed from the spray gun 67 of the fog can be collected by an auxiliary airflow direction rib 168, which is a moisture collection element that runs continuously left and right on the side below the spray gun 67 fog, and evaporate into the air from a position on the auxiliary rib 168 of the direction of air flow. Thus, moisture is collected and returned to the lower container 64 by means of a mist sprayer 67, and the inside of the lower container 64 can be sufficiently moistened and the freshness of the vegetables can be maintained. When mist particles falling down from the mist atomizer 67 are vaporized by an auxiliary airflow direction rib 168, which is an element for collecting moisture, condensation that occurs when water droplets of mist accumulate on the base surface of the vegetable compartment can be prevented.

Since the secondary airflow direction fin 168 is inclined to the left and right, and the end positioned on the higher side is the side equipped with the mist spray 67, even if water droplets fall from the fog atomizer 67 and accumulate on the secondary airflow direction fin 168 , water droplets can evaporate when sliding down a long path along a slope. Therefore, water droplets accumulated on the auxiliary rib 168 of the direction of air flow can evaporate more reliably.

Moisture evaporates from food stored inside the lower container 64 over time from the moment it is placed inside. In this case, the air containing the evaporated moisture exits to the outside of the container from the cold air outlet formed by the recess 69 and the base surface of the upper container 65, along the direction of movement of the cold air entering the lower container 64, and reaches a mist atomizer 67 located nearby The inner part of the atomizer 67 mist through the duct 91 is cooled to be below ambient temperature, and moisture in the air condenses inside the atomizer 67 fog. Water condensate is sprayed in the form of a mist from the cold air outlet formed by the recess 69 and the base surface of the upper container 65 into the interior of the container. As a result, the water evaporated from the stored food, through the atomizer 67 mist again returns to the stored food directly.

The inlet 46 for the vegetable compartment, positioned on the lowest flow of cold air moving through the vegetable compartment, is reduced to the return duct 92 for the refrigerator compartment. As is apparent from the flow of operations, the vegetable compartment 24 is cooled using return cold air from the refrigerator compartment 21. In this case, the return duct 92 of the refrigerator compartment communicates with the vegetable compartment inlet 46 on the outlet side where the cold air of the vegetable compartment exits, typically reduced to the cold air duct on the exit side of another storage compartment, in which case through the duct on the exit side to separate the storage of the temperature zone zhivaniya always moves a large volume of cold air of low temperature than through a duct on the outlet side of the storage compartment temperature of the cooling zone. The speed of movement is thus high, and sometimes the cold air of the storage compartment corresponding to the temperature zone of cooling, such as the vegetable compartment of the present embodiment, is drawn. However, since the cold air flow on the rear surface side is physically shielded by a double rib from the air flow direction rib 68 and the secondary air flow direction rib 168, which are ribs, as in the present embodiment, a decrease in humidity is prevented because the cold air on the back surface side is drawn out from the inlet 46 for the vegetable compartment.

In other words, even if the inlet opening 46 for the vegetable compartment or the outlet side, where the cold air of the vegetable compartment exits, is combined with the duct on the outlet side to separate the storage of the freezing temperature zone with a temperature lower than that in the vegetable compartment, exit from the inlet is prevented. 46 for the vegetable compartment a significant amount of cold air positioned on the side above the auxiliary ribs 168 direction of air flow on the side of the rear surface of the vegetable compartments, and cold air positioned on the side above the auxiliary rib 168 of the direction of air flow can be maintained with high humidity. Therefore, the periphery of the fog atomizer 67 located on the rear surface side becomes a high humidity environment, and an environment is realized in which moisture in the air easily condenses in the interior of the atomizer 67 of the fog.

The lid 66 closes the hole on the upper surface of the upper container 65 to prevent direct contact of cold air with stored foods and their drying. Typically, drinks, such as in PET bottles, are often placed in front of and behind the lower container 64 and the upper container 65, that is, the space is more in front of the lower storage compartment 64a, where cold air is in direct contact with such a part, and a cooling rate is provided .

In the present embodiment, the airflow direction fin 68, used as the moisture introduction member, is continuous on the side of the atomizer 67 of the mist. Cold air introduced into the container (lower container 64, upper container 65) can circulate in the container (lower container 64, upper container 65), and the moisture present in the container (lower container 64, upper container 65) can be transported to the vicinity of the atomizer 67 fog. Moisture can be collected and returned to the container (lower container 64, upper container 65) with a mist spray 67, so that the inside of the container (lower container 64, upper container 65) can be sufficiently moistened and the freshness of vegetables can be maintained.

In the present embodiment, the configuration of the container is comprised of an upper container 65 and a lower container 64, and the gap between the upper container 65 and the lower container 64 is widened in the vicinity of the mist atomizer 67. Moisture from the container (lower container 64, upper container 65) is effectively collected in the vicinity of the mist atomizer 67 and then condenses and is collected by the mist atomizer 67.

In the present embodiment, in the first cooling channel 29 located in the storage compartment (vegetable compartment 24) and including a cold air outlet (outlet for the vegetable compartment 45) and a cold air inlet (inlet 46 for the vegetable compartment), a moisture introduction member has the configuration of the rib 68 of the direction of air flow, made as a whole with the first cooling channel 29. The flow of cold air exiting the container (lower container 64, upper container 65), There is a direction changed by the airflow direction fin 68, so that high humidity cold air can be easily introduced to the vicinity of the mist atomizer 67.

In the present embodiment, the mist sprayer 67 is located on the side of the vegetable compartment inlet 46 than in the center left and right with respect to the vegetable compartment 24. Since the mist sprayer 67 is located on the side of the vegetable compartment inlet 46, where the humidity is higher in left and right, the moisture contained in the cold air can be effectively collected and condensed by the mist atomizer 67, and thus the inside of the container can be sufficient but moistened by microscopic fog, and the freshness of vegetables can be preserved.

In particular, if the damper, which is positioned on the cold air duct upstream of the outlet 45 for the vegetable compartment, is closed to allow cold air to enter the vegetable compartment 24, which is a storage compartment comprising a spray device or a mist spray, i.e. if cold air is not passes from the outlet 45 for the vegetable compartment, creates a stream of cold air from the vegetable compartment 24 to the inlet 46 for the vegetable compartment, although in a small volume, even if the the air does not enter from the outlet for the vegetable compartment 45 because the outlet side of the inlet 46 for the vegetable compartment or the outlet side to which the cold air of the vegetable compartment 24 is in communication with the outlet side of the duct. A similar flow is formed if an ridge is present, although the volume of moving cold air is reduced. In this state, also, the inlet of the vegetable compartment side 46 is in an atmosphere of higher humidity than the center in the left and right directions relative to the vegetable compartment 24, and an environment is obtained in which condensation can easily be carried out in the vicinity of the spray mist 67. Since the mist atomizer 67 is located on the side of the vegetable compartment inlet 46 rather than centrally left and right with respect to the vegetable compartment 24, moisture contained in the cold air can be effectively collected and condensed by the mist atomizer 67, whereby the inside of the container can sufficiently moistened with microscopic fog, and the freshness of vegetables can be preserved.

Since the secondary ridge of the airflow direction 168 is inclined to the left and right, and the end positioned on the upper surface is the side equipped with the atomizer 67 of the fog, even if water droplets fall from the atomizer 67 of the mist and accumulate on the auxiliary ridge of the 168 direction of air flow, water droplets can evaporate when sliding down a long path along a slope. Consequently, water droplets that have accumulated on the auxiliary ridge in the direction of flow 168 can more reliably vaporize.

(Ninth Embodiment)

19 is a perspective view of a vegetable compartment of a refrigerator according to a first embodiment of the present invention. FIG. 20 is a cross-sectional view taken along line 20-20 of FIG. 19, showing details of the vicinity of the mist atomizer 67. On Fig shows a block diagram of the operations of the atomizer 67 fog. The design of the refrigerator as a whole is the same as the design described in the first embodiment. The same numeric reference numbers are assigned to the same elements in the figure of the drawing. The refrigerator compartment 21 as a lower limit for cooling typically has a temperature between 1 ° C and 5 ° C at which freezing does not occur, and the vegetable compartment has a temperature setting between 2 ° C and 7 ° C, which is the same as that for the refrigerator 21 or slightly higher. The freezer compartment 24 is set to the freezing temperature zone and is usually set between -22 ° C and -15 ° C for storage in a frozen state, but can be set to a low temperature between -30 ° C and -25 ° C to enhance the state of frozen storage . The temperature-controlled compartment 22 can switch to a pre-set temperature zone between the cooling temperature zone and the freezing temperature zone other than the cooling temperature zone set between 1 ° C and 5 ° C, for vegetables set between 2 ° C and 7 ° C , and freezing, usually set between -22 ° C and -15 ° C. The temperature-switched compartment 22 is a storage compartment including an independent door provided adjacent to the ice maker 23, and often has a drawer type door. In the present embodiment, the temperature-switched compartment 22 is a storage compartment having a temperature zone of cooling and freezing, but may be a storage compartment adapted to switch only to a temperature zone between cooling and freezing, wherein cooling is assigned to the refrigeration compartment 21 and the vegetable compartment 24 and freezing is assigned to the freezer compartment 25. It may be a storage compartment fixed to a particular temperature zone. An ice maker 23 creates ice using an automatic ice maker (not shown) provided at the top of the compartment, using water supplied from a water tank (not shown) in the refrigerator compartment 21, and stores it in an ice container (not shown) located in bottom of the compartment.

A portion of the roof surface of the inner wall 19 has a shape provided with a step recess in the direction of the rear surface of the refrigerator, where an aggregate compartment 26 is arranged in the step recess to accommodate configuration side components of the high pressure side for the freezing cycle, such as compressor 27, and a dryer (not shown) to remove moisture. In other words, an aggregate compartment equipped with a compressor 27 is included in the rear region in the upper part of the refrigeration compartment 21. The aggregate compartment is provided and the compressor 27 is located in the rear region of the storage compartment on the upper part of the inner wall 19, which is a “dead” space, which is difficult reach out with your hand. Thus, the space of the aggregate compartment, which was located in the lower part of the inner wall 19 in a conventional refrigerator, can be effectively transformed into the (useful) capacity of the storage compartment, thereby significantly improving the operating performance of the enclosure and the usability.

The issues related to the main parts of the invention described below in the present embodiment can be applied to the type of refrigerator in which an aggregate compartment is provided in the rear area of the storage compartment at the very bottom of the inner wall 19, which was typical in the prior art, and in it compressor 27 was located.

The cooling compartment 28 is located on the rear surface of the vegetable compartment 24 and the freezer compartment 25, where an air duct is formed between them to move cold air into each compartment having a heat-insulating property, and a rear partition 111 configured to heat an insulating partition of each compartment. The evaporator 30 is located in the cooling compartment 28, and the cooling fan 31 for purging by forced convection of cold air cooled by the evaporator 30 into the refrigerating compartment 21, the temperature-controlled compartment 22, the ice maker 23, the vegetable compartment 24, and the freezing compartment 25 are located in the upper the space of the evaporator 30. The radiation heater 32, made of a glass tube, for thawing frost and ice adhering to the evaporator 30 and its periphery during cooling, is located in the lower space of the aritel 30. A tray 95 for receiving thawed water generated during thawing, and a drain pipe 86 extending from the deepest part to the outside of the refrigerator are made in the lower part, and an evaporation tray 97 is made on the outside of the refrigerator on the outlet side.

In the vegetable compartment 24, a lower container 64 is mounted on a frame attached to the door 62 of the vegetable compartment 24, and an upper container 65 mounted on the lower container 64.

The lid 66, in order to substantially substantially seal the upper container 65 with the door 62 closed, is held by the first partition 33 and the inner wall 19 at the top of the vegetable compartment 24. When the door 62 is closed, the lid 66 is in close contact with the left and right sides and the far side the upper surface of the upper container 65 and is substantially in close contact with the front side of the upper surface. In addition, the border of the left and right lower sides of the rear surface of the upper container 65 and the lower container 64 fills the gap, so that the moisture of the food storage does not leak out within the absence of contact when moving the upper container 65.

A cold air duct discharged from the vegetable compartment outlet 45 formed in the rear partition 111 is disposed between the lid 66 and the first partition 33. A space is also formed between the lower container 64 and the second partition 34 to form a cold air duct. The inlet 126 for the vegetable compartment 24, designed to return cold air that has cooled the vegetable compartment 24 and exchanged heat with the evaporator 30, is located in the lower part of the rear partition 111 of the rear surface of the vegetable compartment 24.

The issues related to the main parts of the invention described below in the present embodiment can be applied to the type of refrigerator that opens and closes by means of a frame attached to the door and a guide provided on the inner wall, which was typical in the prior art.

The configuration of the rear wall 111 is constituted by a surface 151 of the rear wall made of resin, such as acryl butadiene styrene (ABS, ABS), and thermal insulation material 152 made of expanded polystyrene, in order to separate the duct and the cooling compartment 28 and provide a thermal insulation performance. A recess is formed in one part of the wall surface on the inner side of the storage compartment corresponding to the rear partition 111 so as to have a temperature lower than other locations, and the mist spray 67 is integrated in the corresponding location.

A damper 39 for adjusting cold air to cool each storage compartment is located in a duct through which cold air moves.

The configuration of the mist atomizer 67 is mainly comprised of a mist generation compartment 139, a voltage application means 133 and an outer wall 137, wherein a spray opening 132 and a cold air supply opening 138 are formed in one part of the outer wall 137.

A mist atomizer 67 or a spray device is positioned between the outlet for the vegetable compartment 45 and the inlet 126 for the vegetable compartment in the vertical direction in the vegetable compartment 24.

A mist sprayer 67 or a spray device is located in the vegetable compartment 24, where cold air enters through the outlet for the vegetable compartment 45, which is the cold air outlet to which cold air passes from outside the vegetable compartment 24 when the shutter 39 mounted on the cold air duct opens flow above the vegetable compartment 24. As cold air enters the outside of the vegetable compartment 24 through the vegetable compartment inlet 126, which is the inlet pation cold air in the cold air is discharged from inside the vegetable compartment 24 to the outer side of the vegetable compartment 24, a vegetable compartment 24 is formed a cold air flow path connecting the shortest distance to the outlet opening 45 and the vegetable compartment inlet 126 for vegetable compartment. The spray mist 67 is located in the path of movement of cold air.

In addition, in the present embodiment, the outlet for the vegetable compartment 45, which is the outlet for cold air, is located on the side above the atomizer 67 fog in the storage compartment, which includes the atomizer 67 fog or spray device, and the inlet 126 for the vegetable compartment, which is cold air inlet, located on the side below the mist atomizer 67. The vertical distance of the vegetable outlet and mist spray nozzle 45 is shorter than the distance between the vegetable compartment inlet 126 and the mist spray 67. In other words, the mist atomizer 67 is located on the upper side close to the outlet for the vegetable compartment 45 in the vertical direction.

In addition, the mist spray 67 is located in a portion above the midline 107a in the vertical direction of the vegetable compartment 24. The mist spray 67 is located on the side of the inlet 126 of the vegetable compartment than on the left and right midline 107b of the vegetable compartment 24.

The mist generation compartment 139 is mounted with the spray electrode 135, and the spray electrode 135 is directly or indirectly thermally attached to the heat-conducting pin 134, which is a sufficiently heat-conducting element made of aluminum, stainless steel and the like.

The heat-conducting pin 134 is attached to the wall of the outlet 137, and a configuration directly protruding from the outer shell (sleeve) is attached to the heat-conducting pin 134. An annular disk-shaped electrode 136 of opposite polarity is attached on the storage compartment side at a position facing the spray electrode 135 to maintain a constant distance with the distal end of the spray electrode 135, and the spray hole 132 is provided on its protruding portion.

The voltage applying means 133 is performed near the fog generating section 139, the negative potential side of the voltage applying means 133 for generating high voltage being electrically connected to the spray electrode 135, and the positive potential side is electrically connected to the opposite electrode 136. For example, to the spray electrode 135 an earth voltage (0V) is applied, and a high voltage between 4-10 kV is applied to the opposite electrode 136.

The voltage application means 133 communicates and is controlled by the controller 146 as part of the refrigeration cabinet 1 and turns on / off the high voltage in response to an input signal from the (controller) of the refrigeration cabinet 1 or the atomizer 67 of the fog.

A heater 154 and the like are arranged on the surface 151 of the rear partition wall fixing the fog spray 67, in one part or in the entire area between the surface 151 of the rear wall and the heat-insulating material 152 and the like, for adjusting the temperature of the storage compartment or preventing condensation (on) of the surface and accelerating drying. One part of the heater 154 is installed near the atomizer 67 fog or spray device.

Now, operation and effects with respect to the refrigerator 100 having the configuration as described above will be described. First, the operation of the freeze cycle will be described. The freezing cycle works and the cooling operation is performed upon a signal from the lower control layer (not shown) in accordance with the set temperature of the refrigerator. The coolant of high temperature and high pressure, released as a result of the action of the compressor 27, condenses and is brought into a liquid state to a certain extent by a condensing device (not shown), and the coolant is condensed and brought into a liquid state, while preventing condensation on the refrigerator body through the side surface and the rear surface of the refrigerator body, a refrigerant piping system (not shown) located in the opening of the front surface of the refrigerator body a, and the like, and reaches the capillary tube (not shown). After that, in the capillary tube, its pressure decreases, and heat is exchanged with the suction tube (not shown) to the compressor 27 so that it becomes a liquid coolant of low temperature and low pressure, and it reaches the evaporator 30.

The liquid coolant of low temperature and low pressure carries out heat exchange with air in each storage compartment, such as the exhaust duct 141 of the freezer compartment, which will move according to the action of the cooling fan 31. The coolant in the evaporator 30 evaporates and evaporates. In this case, cold air for cooling each storage compartment is created in the cooling compartment 28. Low temperature cold air is cold air from the cooling fan 31, which is divided into parts for the refrigerating compartment 21, switched by the temperature of the compartment 22, the ice maker 23, the vegetable compartment 24 and the freezer compartment 25, to cool each compartment to target temperature zone.

The refrigerator compartment 21 receives a volume of cold air adjusted by the shutter 39 and cooled to the target temperature zone according to a temperature sensor (not illustrated) located in the refrigerator compartment 21. In particular, the vegetable compartment 24 is controlled to be between 2 ° C and 7 ° C , through the distribution of cold air (not illustrated) and the operation on / off, and usually does not have an “refrigeration” means for determining the temperature in most cases.

The vegetable compartment 24 cools the refrigerator compartment 21, and air is discharged into the vegetable compartment 24 from the outlet for the vegetable compartment 45, made in the middle of the return duct 92 for the refrigerator compartment, for circulating air to the evaporator 30, and moves the air to the outer periphery of the upper container 65 and the lower container 64 to indirectly cool it, and again returns to the evaporator 30 from the inlet 126 of the vegetable compartment 24.

The heat insulator 152 is made with a wall thickness thinner than other locations with respect to one part of the location in the rear wall 111 with a relatively high humidity environment. In particular, the thickness of the heat insulator behind the heat-conducting pin 134 is from about 2 mm to about 10 mm. The rear partition 111 is thus formed with a recess, and the mist atomizer 67 is attached to the corresponding seat.

In the exhaust duct 141 of the freezing compartment 25 on the rear surface of the heat-conducting pin 134, cold air moves created by the cooling system in the evaporator 30 and adjusted from approximately −15 ° C. to −25 ° C. by the cooling fan 31, whereby the heat-conducting pin 134 is cooled to approximately 0 ° C - -10 ° C due to heat conduction from the duct surface. In this case, since the heat-conducting pin 134 is a sufficiently heat-conducting element, heat and cold can be transferred quite sufficiently, whereby the spray electrode 135 is also cooled to approximately 0 ° C. to −10 ° C.

Since the vegetable compartment 24 is between 2 ° C and 7 ° C and is in a relatively high humidity due to evaporation from vegetables and the like, the spray electrode 135 becomes lower or equal to the dew point in temperature and water forms and adheres to the spray electrode 135, including the distal end. With a spray electrode 135 with adhering water droplets as the side of the negative voltage and the opposite electrode 136 as the side of the positive voltage, a high voltage (for example, the spray electrode 135 has 0V (ground (GND), the opposite electrode 136 has 4 to 10 kV)) is applied between the electrodes of the voltage application means 133. In this case, a corona discharge occurs between the electrodes, and the water droplet condensed at the distal end of the spray electrode 135 becomes microscopic due to the electrostatic energy, and according to the Rayleigh function of droplet formation (separation), a microscopic nanoscale fog is generated having charges that cannot be visually visible corresponding to a level of several nm, and the ozone and OH radicals accompanying them, since liquid drops are charged. The voltage to be applied between the electrodes is a very high voltage between 4 and 10 kV, but the discharge current value is at the same time a few μA, and the input value (power) is a very low input value between 0.5 and 1.5 Tue

When a microscopic mist is sprayed, an ion stream is generated from the spray electrode 135. In this case, the high humidity air again moves into the fog generating compartment 139 from the cold air supply opening 138 and thus can be continuously sprayed. In addition, the generated microscopic fog is sprayed into the lower container 64 in the ion stream and diffusible because the fog is a very small microscopic particle, and the microscopic fog also reaches the upper container 65. The microscopic fog to be sprayed has a negative charge because it is created by discharge high voltage.

Green vegetables, fruits, and the like from vegetables or vegetables and fruits are stored in the vegetable compartment 24, and such vegetables and fruits easily deteriorate by evaporation or evaporation during storage. Vegetables and fruits stored in the vegetable compartment 24 typically include those that are slightly spoiled by evaporation upon return of (just) purchased or by evaporation during storage, and have a positive charge. Thus, atomized mist tends to collect on the surface of vegetables, whereby the preservation of freshness may increase. Microscopic fog of the nano level, coupled to the surface of vegetables, significantly contains OH radicals and ozone, although in a very small volume, which has sterilization, antibacterial, elimination of bacteria and, in addition, causes an increase in nutrients in vegetables, such as vitamin C, by eliminating agrochemicals by oxidative decomposition and antioxidation.

If water is absent on the spray electrode 135, the discharge distance diverges, the insulating layer of air cannot be broken, and the discharge phenomenon does not occur. Thus, no current flows between the spray electrode 135 and the opposite electrode 136. The high voltage of the high voltage application means 133 can be turned on / off as a result of the detection by the controller 146 of the refrigerator 100.

In addition, since the heat-conducting pin 134 is typically cooled by cold air from about −15 ° C. to −25 ° C., condensation may occur in excess due to the environment in the vegetable compartment 24. In the present embodiment, the vegetable compartment 24 is cooled by return air from the refrigerator compartment 21 The refrigeration compartment 21 is controlled by a shutter 39 so as to be in the target temperature zone as described above. In other words, if the temperature of the refrigerator compartment 21 is higher than the target temperature, the shutter 39 is opened for cooling. According to this action, relatively dry air after the cooling refrigerator compartment 21 passes into the vegetable compartment 24 from the outlet for the vegetable compartment 45 through the inlet duct 140 of the refrigerator compartment 21 and cools the vegetable compartment 24. Water droplets excessively condensed on the spray electrode 135 are dried using dry air so that condensed volume can be sprayed. A control operation thereof will be described using the flowchart of the fog atomizer of FIG.

First, it is determined whether the refrigerator compartment 21 is higher or lower with respect to the set temperature (step 1). If higher (YES), the shutter 39 is opened to cool the refrigerator compartment 21 (step 2). Here, relatively dry air or dry air after the cooling refrigerator compartment 21 passes into the vegetable compartment 24 from the outlet 45 for the vegetable compartment. Water droplets excessively condensed on the spray electrode 135 are dried with such dry air. In other words, the fog generating compartment 139 is drained by a drying means. In the present embodiment, dry air refers to a dehumidifier rather than storage compartment air, including a fog generating compartment 139. For example, in the case of cold air, after the cooling refrigerator compartment 21, dry air is such that the temperature is usually 3 ° C, relative humidity (obtained by dividing the amount of water vapor contained in the atmosphere at a certain temperature (absolute humidity of the mass) by the amount of saturated water steam at an appropriate temperature) is approximately 30% and the absolute humidity (indicating the amount of water vapor contained in a unit mass of dry air per mass) has a very small a low humidity value of 0.00140 kg / kg. The air (cold air) near the mist generation compartment 139 has a temperature of 1 ° C and a relative humidity of about 80 to 100%, and thus it is believed that the absolute humidity at a relative humidity of 100% will be 0.00406 kg / kg.

Therefore, when dry air moves to the vicinity of the mist generation compartment 139, the absolute humidity near the spray electrode decreases and the evaporation of water droplets adhered to the spray electrode is promoted to obtain an equilibrium state at the boundary. When using dry air for a drying agent, the drying is facilitated the greater, the greater the difference in absolute humidity, and dry air can be used as a drying agent if the absolute humidity near the fog generation compartment 139 with respect to at least dry air is greater or equal to two times and preferably greater than or equal to three times.

During the drainage operation, the application of the high voltage to the mist atomizer 67 is turned off (OFF) and condensation with respect to the mist generation portion 139 is not performed (step 3). If the set temperature is low (NO), the shutter 39 is closed to prevent cooling of the refrigerator compartment 21 (step 4). In this case, since cold air does not enter the vegetable compartment 24, a high humidity environment is obtained by evaporation from vegetables, etc., stored in the vegetable compartment 24, where during this operation, the application of high voltage to the fog sprayer 67 is turned on (step 5), so that the spray electrode 135 is cooled, condensation occurs at the distal end, spraying starts and spraying of the mist is performed.

Therefore, the fog generation compartment 139 repeatedly sprays the mist to spray the mist into the storage compartment, and is dried by the drying means, that is, the drying of the fog generation compartment 139 is always performed by the drying means before the fog generation compartment 139 performs the spray. Therefore, since the mist generation compartment 139 is always dried before spraying, excessive condensation is prevented, and mist of a more stable spray amount can be sprayed, thereby providing a user-friendly refrigerator that prevents condensation inside the refrigerator and increases freshness retention.

Spraying can be performed stably and optionally by turning ON / OFF to apply a high voltage to the mist atomizer 67 in accordance with the condensation state of the atomizer electrode 135. In addition, energy consumption can be reduced.

The lid 66 closes the hole on the upper surface of the upper container 65 to prevent cold air from directly contacting and dehydrating stored food. Typically, drinks, such as in PET bottles, are often placed in space in front and behind the lower container 64 and the upper container 65, where cold air is in direct contact with such a part, and a cooling rate is provided.

The mist atomizer 67 is cooled so that the mist generation compartment 139 corresponds to a temperature below the dew point, and is configured so that moisture in the air condenses in the mist generation compartment 139. The water condensate is converted into microscopic fog through the mist generation compartment 139 and is dispersed into a container from the gap of the lower container 64 and the upper container 65, positioned on the side below the spray gun 67 fog.

Part of the cold air entering from the outlet for the vegetable compartment 45 is discharged from the inlet 126 of the vegetable compartment through the rear surface of the lower container 64 and the upper container 65. Cold air or dry air entering from the outlet 45 for the vegetable compartment moves to the lower surface along the rear surface of the container, and a mist atomizer 67 is disposed on a cold air path connecting the inlet 126 of the vegetable compartment and the outlet 45 for the vegetable compartment Iya on the shortest path. Therefore, if cold air enters from the outlet 45 for the vegetable compartment, dry air or relatively dried cold air, which is a drying means, moves around the perimeter of the spray device.

In the present embodiment, a mist sprayer 67 is located in the vegetable compartment 24 between the outlet for the vegetable compartment 45 and the inlet 126 of the vegetable compartment in the vertical direction. Since cold air enters through the outlet for the vegetable compartment 45, which is the outlet for cold air, from the outside of the vegetable compartment 24, and as cold air enters the outside of the vegetable compartment 24 through the inlet 126 of the vegetable compartment, which is the cold air inlet, in the vegetable compartment 24, a cold air path is formed connecting the vegetable compartment inlet 126 and the vegetable compartment outlet 45 via the shortest path. A mist atomizer 67 is located in the path of the cold air, where the volume of cold air moving through the vegetable compartment 24 is significant.

Since the volume of moving cold air is large in the path of movement of cold air, where the cold air entering the storage compartment from the outlet for the vegetable compartment 45 moves outside the vegetable compartment 24 through the inlet 126 of the vegetable compartment, the speed of movement of the cold air becomes relatively high, and the mist generation compartment 139 in the mist atomizer 67 can be dried with relatively dried cold air entering the storage compartment from the vegetable outlet 45 i. In other words, cold air is a drying agent.

In addition, in the present embodiment, the outlet for the vegetable compartment 45, which is the outlet for cold air, is located on the side above the atomizer 67 fog in the storage compartment 24, including the atomizer 67 fog. The vegetable compartment inlet 126, which is the cold air inlet, is located on the side below the mist atomizer 67. The vertical distance of the vegetable outlet and mist spray nozzle 45 is smaller than the distance between the vegetable compartment inlet 126 and the mist spray 67. In other words, the mist atomizer 67 is located on the upper side close to the outlet for the vegetable compartment 45 in the vertical direction.

Microscopic fog created in the mist spray 67 can move in a stream of large volume of cold air entering from the vegetable compartment outlet 45, and the mist generation compartment 139 in the spray device can more effectively dry according to the location of the mist spray 67 on the side close to the outlet 45 for the vegetable compartment, which is the outlet of cold air, in the vertical direction.

The mist sprayer 67 is located on the midline 107a in the vertical direction from or on the side above the midline 107a in the vertical direction of the vegetable compartment 24 in the vegetable compartment 24 including the mist sprayer 67. Thus, the microscopic fog created in the mist sprayer 67 from the upper side can move in a stream of cold air moving through the vegetable compartment 24, applying the characteristics that the cold air moves to the lower surface. As the relatively dried cold air entering from the outlet for the vegetable compartment 45, which is the outlet for cold air, moves around the perimeter of the spray device before becoming highly wet in the vegetable compartment 24, when the spray device is located on the side upstream of the cold air moving through the vegetable compartment 24, the drained cold air becomes a more effective drying agent.

The spray mist 67 is located on the side of the inlet 126 of the vegetable compartment, rather than on the midline 107b in the horizontal direction of the vegetable compartment 24. According to the location of the spray 67 mist on the side of the inlet 126 of the vegetable compartment, where the flow of cold air becomes larger left and right, the speed of movement of cold air becomes relatively high, since the volume of moving cold air is significant, and in the situation that cold air enters the storage compartment from the outlet 45 for the vegetable compartment, the mist generation compartment 139 in the mist atomizer 67 can be more efficiently dried with relatively dried cold air. In other words, cold air is a drying agent.

In the present embodiment, it has been described that control is performed to turn off the application of a high voltage to the mist spray 67 when the shutter 39 is opened, but the present embodiment is not limited to such control. For example, when the outside temperature is determined and the outside temperature is a relatively high temperature, the operation of opening the shutter 39 is relatively increased, and thus, it becomes difficult for the vegetable compartment 24 to be in a high humidity state. In such a case, it is preferable to actively spray the condensed water droplets by incorporating a high voltage application. If the outside temperature is relatively low, the shutter 39 is often closed and the spray electrode 135 tends to easily reach an overcondensation state, and thus, a high voltage application operation can be performed, and the spray gun 67 can be activated by the compressor 27 .

In the present embodiment, it has been described that the drying means for drying the excessive condensation of the spray electrode 135 is dry air, but a heater, etc., can be used as the drying means to prevent excessive condensation on the rear surface of the spray gun 67 of the mist. For example, even in the operating state, when it is difficult for dry air to enter, for example, during low outside temperature or when the cooling of the storage compartment is not necessary, the fog generating section 139 can be dried at arbitrary times regardless of the operating state. In addition, the condensation state of the spray electrode 135 may be stable. Therefore, the mist generation compartment 139 can be more stably dried by using dry air in combination for the drying means, thereby preventing excessive condensation.

In the present embodiment, a shutter 39 is used to dry the spray electrode 135, but means can be used to cool each storage compartment to actively assist in draining the mist generation compartment 139 with a dedicated fan. In this case, control of the application of the high voltage to the mist atomizer 67 can be performed according to the action of such a fan, and similar effects can be obtained.

In the present embodiment, the duct for cooling the heat-conducting pin is the exhaust duct of the freezer compartment, but there may be a low-temperature duct, such as an exhaust duct of an ice maker and a return duct of the freezer compartment. Thus, the installed area of the atomizer 67 fog is increased.

In the present embodiment, the water-retaining material is not mounted on the periphery of the spray electrode 135 of the mist sprayer 67, but the water-retaining material can be mounted. The condensate created near the spray electrode 135 can thus be held at the periphery of the spray electrode 135 and can be properly supplied to the spray electrode 135.

In the present embodiment, the refrigerator storage compartment is a vegetable compartment 24, but there may be a storage compartment for other temperature zones, such as a refrigerator compartment 21 and a temperature-switched compartment 22, in which various applications can be developed.

In the present embodiment, the negative potential side in the voltage application means 133 for generating high voltage is electrically connected to the spray electrode 135, and the positive potential side is electrically connected to the opposite electrode 136, and a high voltage of -4 to -10 kV can be applied to a spray electrode 135 and a zero potential (0V) can be applied to the opposite electrode 136. In this case, the microscopic mist created contains a larger volume m OH radicals, oxidizing ability which can remove odor in the vegetable compartment and may provide antibacterial property and sterilization of vegetable surfaces, while at the same time, oxidation decomposes and removes harmful substances such as agrochemical substances and wax adhered to the vegetable surface.

In the present embodiment, the distribution of heat from the duct through which cold air moves to cool each storage compartment formed in the evaporator is used for cooling means, but cooling means using a Peltier element may also be considered. In this case, dry air can be used as a drying means similar to the first embodiment. However, using the characteristics of the Peltier element, the cooling surface can be used as a heating surface by inverting the input, and thus drying can be performed by heating a heat-conducting pin. In this way, the condensation and dehumidification cycle can be more stably controlled.

In addition, in the present embodiment, cooling means is included in the configuration, so that the spray electrode 135 has a temperature lower than or equal to the dew point and moisture in the air condenses in the spray electrode 135. Consequently, condensation from excess water can easily and reliably occur in the spray electrode steam in the storage compartment. Thus, a microscopic fog of the nano level is created by a high-voltage corona discharge with respect to the opposite electrode 136, and the fine-droplet and sprayed microscopic fog evenly adheres to the surface of vegetables and fruits, for example vegetables, as a result of which suppresses evaporation from fruits and vegetables and increases the preservation of freshness . Moisture enters cells from (inter) cell gaps and air cavities on the surface of fruits and vegetables and is fed into damaged cells to restore the cell to a fresh state.

Since a discharge occurs between the spray electrode 135 and the opposite electrode 136, the spray direction can be set by stably creating an electric field and microscopic fog can more easily be sprayed into the container.

Thanks to ozone and OH radicals generated simultaneously with the generation of fog, effects such as odor removal, harmful substances removal and pollution prevention can be enhanced.

The spray mist can be directly sprayed onto foodstuffs in a vegetable container, and the mist can adhere to the surface of vegetables using fog and the potential of vegetables, whereby the freshness preservation efficiency is sufficient.

In addition, a water tank, etc., is unnecessary, since excess water vapor in the storage compartment condenses in the spray electrode, water droplets adhere and mist is sprayed, and since a water supply means such as a pump and capillary are not used, this may be inexpensive in configuration.

Since water condensate is used instead of tap water and since there are no mineral components and impurities, the deterioration that occurs when using a water-retaining material or the deterioration of the water-holding characteristic due to clogging can be prevented.

In the present embodiment, the water tank is unnecessary because it is not ultrasonic atomization by ultrasonic vibrations, and the influence of the temperature of the inside of the refrigerator is small because the consumption is small. In addition, since excess fog is not sprayed to hold the interior of the refrigerator with high humidity, generation of excess condensation is prevented in this case.

In addition, since the portion containing the voltage application means 133 is built into the rear wall and cooled, the temperature of the lower layer can be prevented. Thus, the influence of the temperature of the inside of the storage compartment can be reduced.

In the present embodiment, an evaporator for cooling each storage compartment and a partition for heat-insulating separation of the evaporator and storage compartment are provided, and a mist atomizer 67 is connected to the partition. Thus, by performing the installation in the gap between the storage compartment, the useful (capacious) capacity does not decrease, and due to attachment to the back, a person will not be able to easily reach it with his hand, and thus, safety is increased.

In the present embodiment, the cooling means for cooling the spray electrode of the atomizer 67 of the mist and effecting condensation thereon is a metal element having sufficient heat conductivity, and the means for cooling the metal element is heat distribution from the duct through which the cold air created by the evaporator moves. Thus, the temperature of the heat-conducting pin and the spray electrode can be easily set by adjusting the wall thickness of the heat insulator, and the cold air of the “cold” temperature does not leak to the outside by interlacing the heat-insulating material, and thus frost sticking, condensation and the like for the outside can be prevented shell in this case.

In the present embodiment, the partition with the attached mist spray 67 has a recess in one part on the surface of the storage compartment, where a metal element or cooling means of the mist spray 67 is inserted into it.

Therefore, there is no effect on the storage volume of stored fruits and vegetables and food products, the metal element is reliably cooled, and in relation to other parts, wall thickness can be provided in order to provide thermal insulation performance, and thus, condensation can be prevented in this case, and reliability may increase.

Ozone is also formed during the generation of microscopic fog. The ozone concentration in the storage compartment can be controlled by the ON / OFF operation of the fog atomizer 67. Deterioration (quality) of vegetables, such as discoloration due to ozone excess, can be prevented, and the sterilization and antibacterial effects on the surface of vegetables can be increased by appropriately adjusting the ozone concentration.

(Tenth embodiment)

On Fig shows a cross section of the vicinity of the vegetable compartment of the refrigerator according to the tenth embodiment of the present invention. The same numeric reference numbers are indicated for configurations that are the same with the ninth embodiment, and a detailed description thereof will be omitted. Other executions and effects in the tenth embodiment, which are similar to the ninth embodiment, or may be applied with it, will be omitted.

As shown in FIG. 22, a mist atomizer 67 is integrated in a second partition 34 providing a thermal insulation characteristic to separate the temperature zone of the vegetable compartment 24 and the ice maker 23, and in particular, the insulation material has a shape with a recess in relation to the heat-conducting pin 134 or section 139 fog generation.

Below will be described the operations and effects of the refrigerator having the configuration as described above. The thickness of the second partition 34 mounted with the spray gun 67 requires cooling to cool the heat-conducting pin 134 thermally bonded directly or indirectly to the spray electrode 135. The wall thickness of the seat equipped with the spray gun 67 is thinner than other parts. Thus, the heat-conducting pin 134 is cooled as a result of heat conduction from the ice maker 23 of a relatively low temperature, and the spray electrode 135 can be cooled. If the temperature of the distal end of the spray electrode 135 is lower or equal to the dew point temperature, water vapor near the spray electrode 135 condenses on the spray electrode 135 and water droplets are reliably created.

Since the heat-conducting pin 134 is constantly cooled due to the thermal conductivity of cold air from about −15 ° to −20 ° C from the ice maker 23 of a relatively low temperature, condensation may occur excessively due to the environment in the vegetable compartment 24. In the present embodiment, the vegetable compartment 24 is cooled by the return air of the refrigerator compartments 21. The refrigeration compartment 21 is controlled by a flapper 39 so as to be a target temperature zone. In other words, the refrigerator compartment 21 is cooled by opening the shutter 39 if the temperature is higher than the target. According to the operation, the relatively dry air after the cooling refrigerator compartment 21 thus passes into the vegetable compartment 24 from the outlet for the vegetable compartment 45 through the inlet duct 140 of the refrigerator compartment 21, thereby cooling the vegetable compartment 24. Water droplets that are excessively condensed on the spray electrode 135 are dried using such dry air, so that the volume of condensate is in a spray state. The control operation is similar to that of the ninth embodiment, and thus, details will be omitted.

Although not illustrated, by installing a temperature sensor inside the refrigerator, a humidity sensor inside the refrigerator, and the like, the dew point temperature can be obtained more accurately in accordance with a change in the environment inside the refrigerator by a predetermined calculation.

A high voltage (e.g., 7.5 kV) is applied between the electrodes by the voltage application means 133 in the state with the spray electrode 135 as the side of the negative voltage and the opposite electrode 136 as the side of the positive voltage. In this case, a breakdown of the (air) insulation layer between the electrodes is carried out and a corona discharge occurs, the water of the spray electrode 135 is sprayed from the distal end of the electrode, and a microscopic fog of a nano level with a charge of less than 1 micron, which cannot be visually recognized, as well as ozone, OH -radicals and the like, accompanying such.

The generated microscopic fog is sprayed into the vegetable compartment 24. The microscopic fog sprayed from the fog spray 67 has a negative charge. Vegetables or fruits and vegetables are stored in the vegetable section 24, and greens and fruits are also stored. Such vegetables and fruits are usually stored in a slightly spoiled state as a result of evaporation upon return of the purchased or evaporation during storage. Such fruits and vegetables are usually charged with a positive charge, and atomized microscopic fog having a negative charge tends to collect on the surface of the vegetables. Thus, the sprayed microscopic fog again allows the inside of the vegetable compartment 24 to be in a (state) high humidity and at the same time adheres to the surface of fruits and vegetables, thereby suppressing evaporation from fruits and vegetables and increasing the preservation of freshness. Penetrating into the cells from the intercellular spaces of fruits and vegetables, moisture evaporates and is again supplied to the spoiled cells, so that the problem of decay is solved by turgor pressure (on the walls of plant) cells, and the fresh state is restored.

The generated microscopic fog contains ozone, OH radicals, and the like, which carry significant oxidative power. Thus, the generated microscopic fog can remove odor in the vegetable compartment 24, and the antibacterial and sterilization effects can be provided on the surface of the vegetables, while harmful substances such as agrochemicals and wax adhered to the surface of the vegetables can decompose and be removed as a result oxidation.

Currently, from the point of view of preserving the Earth’s environment, the use of isobutene having a small overall heating coefficient is generally accepted for the coolant of the freezing cycle. Isobutene or carbon hydride has a specific gravity of approximately two at atmospheric pressure (2.04, 300 K) compared to air at normal temperature. If isobutene seeps out of the freezing system when compressor 27 is stopped, isobutene passes to the bottom surface because it is heavier than air. In this case, the coolant has the possibility of seeping (heat gain) into the refrigerator from the rear wall 111. In particular, when seeping from the evaporator 30, where the accumulation of coolant is large, the amount of heat gain can increase if the vegetable compartment 24 is equipped with a spray 67 of fog installed above the evaporator 30, and thus does not pass into the vegetable compartment 24, even if a leak occurs.

Even if it has passed into the vegetable compartment 24, the coolant accumulates on the lower part of the storage compartment, since it is heavier than air. The mist atomizer 67 is mounted on the upper surface of the storage compartment, and thus, the possibility that the vicinity of the mist atomizer 67 becomes combustible is very low.

Therefore, the present embodiment includes a partition to separate the storage compartment and the low-temperature storage compartment, on the side of the upper surface of the storage compartment, and a mist atomizer 67 is attached to the partition of the upper surface. Thus, if the storage compartment of the temperature freezing zone, such as the freezer compartment and the ice maker, is located in the upper part, it is mounted on the bulkhead of the upper surface separating it, and the spray electrode of the fog atomizer 67 is cooled and conducts condensation using a cooling source. Therefore, a special cooling device is unnecessary, and spraying can be carried out from the top surface and, thus, can be dispersed into the container as a whole, and safety is increased, since it is less likely that a person touches his hand.

The fog generation compartment of the present embodiment creates fog through an electrostatic spraying method, splits and segments water droplets using electrical energy, such as high voltage, to create microscopic fog. Since the fog generated is charged, the adhesion to vegetables and fruits can be increased by providing a charge opposite to the object to be bonded, such as vegetables and fruits, with respect to the fog, for example a spray fog charged with a negative charge towards vegetables having a positive charge. The fog adheres more evenly to the surface of vegetables, and the adhesion rate of the fog can be increased compared to an uncharged fog. The atomized microscopic fog can be directly sprayed onto foodstuffs in a vegetable storage container, and the microscopic fog can be attracted to the surface of vegetables using microscopic fog and the potential of vegetables, whereby the freshness retention can be increased.

In addition, the make-up water of the present embodiment uses condensate instead of tap water supplied from the outside. Mineral components and impurities are thus not present, and deterioration (of the parameters) of the distal end of the spray electrode and deterioration of the moisture retention characteristic due to clogging can be prevented.

In addition, since the fog of the present embodiment contains radicals, agrochemicals, wax, and the like adhered to the surface of vegetables can be decomposed and removed using a very small volume of water, whereby water can be saved and lower consumption can be achieved.

The present embodiment includes means for adjusting the amount of airflow to adjust the amount of dry air, moreover, the fog atomizer 67 may determine the application of high voltage for the means for applying voltage along with the opening / closing operation of the means for adjusting the amount of flow, and water droplets adhering to the compartment mist generation (spray electrode) can be dried without using a new drying agent. Thus, the water vapor in the storage compartment to be condensed in the mist generation compartment (spray electrode) can be easily and reliably condensed in the mist generation compartment (spray electrode), and the condensation volume can be controlled so that the spraying is stable and continuous. Since a new cooling medium is not used, its configuration can be inexpensive and simple.

The fog generation compartment 139 can determine (if necessary) applying a high voltage to the voltage application means together with the opening / closing operation of the shutter 39. Thus, if water droplets are not present in the fog generation compartment 139 (spray electrode 135) or if excessively condensed, the application of high voltage can be prevented until the state of the possibility of atomization of the condensate is realized, and thus additional power can be restrained.

The mist generation compartment may determine the application of a high voltage to the voltage applying means 133 together with the action of the cooling fan 31, the cooling fan 31 being configured to supply cold air to each storage compartment from the evaporator 30 to cool the storage compartment. Thus, if water droplets are not present in the mist generation compartment 139 (spray electrode 135) or if excessively condensed, the application of high voltage can be prevented until the condensation atomization condition is realized, and thus the use of additional power can be prevented.

INDUSTRIAL APPLICABILITY

The refrigerator according to the present invention sufficiently moisturizes the interior of the container and maintains the freshness of the stored food by efficiently collecting and re-spraying moisture from the stored food. Not being a limited domestic refrigerator, it can be used for an industrial refrigerator, food storage and refrigerated trucks.

Claims (9)

1. A refrigerator comprising a thermally insulated sectional storage compartment, a mist atomizer disposed in the storage compartment, and drying means for drying the mist atomizer, wherein the mist atomizer condenses moisture in the air in the storage compartment and sprayes it into the storage compartment in the form of fog. 2. The refrigerator according to claim 1, in which the fog atomizer uses an ultrasonic method. 3. The refrigerator according to claim 1, wherein the mist atomizer includes voltage application means for generating a potential difference and a spray electrode electrically connected to voltage application means, the drying means drying the spray electrode. 4. The refrigerator according to claim 3, further comprising a cooling fan for supplying cold air from the evaporator to each storage compartment to cool the storage compartment, the mist atomizer determining the application of high voltage by means of applying voltage with respect to the action of the cooling fan. 5. The refrigerator according to claim 1, which is configured to spray mist repeatedly, wherein the mist atomizer condenses moisture in the air and atomizes it in the form of fog into the storage compartment, and dehumidifies it with a drying agent. 6. The refrigerator according to claim 1, in which the drying means carries out the drying using dry air. 7. The refrigerator according to claim 6, in which the dry air is cold air to cool the storage compartment. 8. The refrigerator according to claim 6, further comprising a damper for adjusting the amount of dry air flow. 9. The refrigerator of claim 8, in which the mist atomizer determines the application of high voltage means voltage application in combination with the operations of opening / closing the damper.

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