JP6986109B2 - refrigerator - Google Patents

Description

Embodiments of the present invention relate to a refrigerator.

In recent years, in household refrigerators, it is known that a mist releasing means for discharging mist is provided in the refrigerator body so that the mist released from the mist releasing means is supplied to the storage chamber.

Japanese Unexamined Patent Publication No. 2006-57999

In a refrigerator provided with a mist discharging means, it is required to efficiently supply the generated mist to the storage chamber.

Therefore, a refrigerator capable of efficiently supplying mist to the storage room is provided.

The refrigerator of the present embodiment cools the heat insulating box body constituting the refrigerator body, a partition plate for partitioning the inside of the heat insulating box into a plurality of storage chambers, a heat insulating material having higher heat insulating properties than the partition plate, and the storage chamber. The cooler is provided with a cooler for discharging the mist and a mist discharging means for discharging the mist, the cooler is provided above the mist discharging means, and the heat insulating material does not hold the mist discharging means. In addition, the heat insulating box body in the region provided between the cooler and the mist discharging means, separated from the mist discharging means, and provided with the mist discharging means. The distance that the heat insulating material is separated from the mist discharging means is longer than the distance that the heat insulating material is separated from the cooler.

Longitudinal side view showing the schematic configuration of the entire refrigerator according to the first embodiment. Front view of the refrigerator body without doors and shelves Schematic perspective view near the chilled room Enlarged front view around the duct for mist In FIG. 4, a cross-sectional plan view along the X1-X1 line. Longitudinal side view along line X2-X2 in FIG. Longitudinal side view along line X3-X3 in FIG. Longitudinal side view along X4-X4 line in FIG. Longitudinal front view of the electrostatic atomizer part FIG. 4 equivalent diagram according to the second embodiment Longitudinal side view along line X5-X5 in FIG. Fig. 9 equivalent diagram FIG. 9 equivalent diagram according to the third embodiment

Hereinafter, refrigerators according to a plurality of embodiments will be described with reference to the drawings. In each embodiment, substantially the same constituent parts are designated by the same reference numerals, and the description thereof will be omitted.
(First Embodiment)
First, the first embodiment will be described with reference to FIGS. 1 to 9. As shown in FIGS. 1 and 2, the refrigerator main body 1 is configured by providing a plurality of storage chambers in a vertically long rectangular box-shaped heat insulating box body 2 having an open front surface. Specifically, in the heat insulating box 2, a refrigerating room 3 and a vegetable room 4 are provided in order from the upper stage, and an ice making room 5 and a small freezing room 6 are provided side by side below them, and below them. A freezing room 7 is provided. A well-known automatic ice making device 8 (see FIG. 1) is provided in the ice making chamber 5. The heat insulating box 2 is basically configured by providing a heat insulating material 2c between the outer box 2a made of steel plate and the inner box 2b made of synthetic resin.

The refrigerating room 3 and the vegetable room 4 are both storage rooms in a refrigerating temperature range (for example, 1 to 5 ° C.), and are partitioned above and below by a plastic partition plate 10. It is said that the temperature of the refrigerator compartment 3 is preferably about 4 ° C., and the temperature of the vegetable compartment 4 is preferably about 5 ° C., which is slightly higher than that. A hinge opening / closing type heat insulating door 3a is provided on the front surface of the refrigerating room 3, and a drawer type heat insulating door 4a is provided on the front surface of the vegetable room 4. A lower case 11 constituting a storage container is connected to the back surface of the heat insulating door 4a. An upper case 12 smaller than the lower case 11 is provided on the upper part of the lower case 11.

The inside of the refrigerating room 3 is divided into a plurality of upper and lower stages by a plurality of shelf boards 13. As shown in FIG. 3, at the lowermost part (upper part of the partition plate 10) in the refrigerator compartment 3, a chilled chamber 14 is provided on the right side, and an egg case 15 and an accessory case 16 are provided on the left side thereof. Further, a water storage tank 17 is provided on the left side of these tanks. The chilled chamber 14 is provided with a chilled case 18 that can be taken in and out. The chilled chamber 14 also constitutes a storage chamber. The temperature of the chilled chamber 14 is preferably about 0 ° C. The water storage tank 17 is for storing water to be supplied to the ice tray 8a of the automatic ice making device 8.

The ice making chamber 5, the small freezing chamber 6, and the freezing chamber 7 are all storage chambers in the freezing temperature range (for example, −10 to −20 ° C.), and the vegetable chamber 4, the ice making chamber 5, and the small freezing chamber 6 are included. The space is partitioned up and down by a heat insulating partition wall 19. A drawer-type heat insulating door 5a is provided on the front surface of the ice making chamber 5, and an ice storage container 20 is connected to the back surface of the heat insulating door 5a. Although not shown, a drawer-type heat insulating door to which a storage container is connected is also provided on the front surface of the small freezing chamber 6. A drawer-type heat insulating door 7a to which a storage container 22 is connected is also provided on the front surface of the freezing chamber 7.

Although not shown in detail as a whole, the refrigerator main body 1 contains a refrigerating cooler 24 (cooler) for cooling the refrigerating chamber 3 and the vegetable compartment 4, the ice making chamber 5, the small freezing chamber 6, and the like. A refrigeration cycle comprising two coolers with a refrigerating cooler 25 for cooling the freezer chamber 7 is incorporated. A machine room 26 is provided on the back side of the lower end portion of the refrigerator body 1, and although not shown in detail, a compressor 27 and a condenser and the like constituting a refrigerating cycle are arranged in the machine room 26. , A cooling fan for cooling them, a defrosting water evaporating dish 28, and the like are arranged. A control device 29 equipped with a microcomputer or the like for controlling the entire refrigerator is provided in a portion near the lower part of the back surface of the refrigerator body 1.

A freezing cooler chamber 30 is provided on the back of the freezing chamber 7 in the refrigerator main body 1. In the freezing cooler chamber 30, the freezing cooler 25, a defrosting heater (not shown) and the like are arranged at the lower part, and the freezing blower 31 is located at the upper part. It is arranged. A cold air outlet 30a is provided in the middle portion of the front surface of the freezing cooler chamber 30, and a return port 30b is provided in the lower end portion.

In this configuration, when the freezing blower 31 is driven, the cold air generated by the freezing cooler 25 is supplied from the cold air outlet 30a into the ice making chamber 5, the small freezing chamber 6, and the freezing chamber 7. The circulation is such that the return port 30b is returned to the freezing cooler chamber 30. As a result, the ice making chamber 5, the small freezing chamber 6, and the freezing chamber 7 are cooled. A drainage gutter 32 for receiving the defrosted water at the time of defrosting of the refrigerating cooler 25 is provided in the lower portion of the refrigerating cooler 25. The defrosted water received in the drainage gutter 32 is guided to the defrosted water evaporating dish 28 provided in the machine room 26 outside the refrigerator and evaporates.

Then, in the back of the refrigerating chamber 3 and the vegetable compartment 4 in the refrigerator main body 1, the refrigerating cooler 24 and the cold air generated by the refrigerating cooler 24 are put into the refrigerating chamber 3 (and the vegetable compartment 4). A cold air duct 34 (duct) for supplying the inside, a refrigerating blower 35 (blower) for circulating the cold air, and the like are arranged as follows. That is, a refrigerating cooler room 36 forming a part of the cold air duct 34 is provided behind the lowermost stage of the refrigerating room 3 in the refrigerator body 1 (behind the chilled room 14), and the refrigerating cooler room 36 is provided. A refrigerator 24 for refrigeration is arranged in 36.

A cold air supply duct 37 extending upward is provided above the refrigerating cooler chamber 36, and the upper end portion of the refrigerating cooler chamber 36 communicates with the lower end portion of the cold air supply duct 37. In this case, the refrigerating cooler chamber 36 and the cold air supply duct 37 constitute the cold air duct 34. The front wall 36a of the refrigerating cooler chamber 36 bulges forward from the cold air supply duct 37. As shown in FIGS. 6 to 8, a lower bulging portion 36c that bulges forward from the front wall 36a is provided below the front wall 36a, and the upper front wall 36a is provided. A step portion 36b is formed between the lower portion and the lower bulging portion 36c. A heat insulating material 38 having a heat insulating property is provided on the back side of the front wall 36a. A plurality of cold air supply ports 39 that open into the refrigerating chamber 3 are provided in the front portion of the cold air supply duct 37.

At the lower part of the refrigerating cooler chamber 36, a drainage gutter 40 located below the refrigerating cooler 24 and receiving defrost water from the refrigerating cooler 24 is provided. The defrosted water received in the drainage trough 40 is also guided to the defrosted water evaporation tray 28 provided in the machine chamber 26 outside the refrigerator, similarly to the defrosted water received in the drainage trough 32. It is designed to evaporate. The left-right length dimension and the front-rear depth dimension of the drainage trough 40 are set to be larger than the left-right length dimension and the front-rear depth dimension of the refrigerating cooler 24, and defrosting dripping from the refrigerating cooler 24. It is sized to receive all the water.

Behind the vegetable compartment 4, the refrigerating blower 35 is disposed below the drainage gutter 40, and a ventilation duct 42 and a suction port 43 are provided. The air duct 42 communicates with the refrigerating cooler chamber 36 (cold air duct 34) so that the upper end thereof circulates around the drainage gutter 40. The suction port 43 is open in the vegetable compartment 4. As shown in FIG. 5, communication ports 44 are formed at both left and right corners of the rear portion of the partition plate 10 constituting the bottom of the refrigerating chamber 3 (only the communication port 44 on the right side is formed in FIG. 5). show). The communication port 44 communicates the refrigerating room 3 with the vegetable room 4 below the refrigerating room 3.

In this configuration, when the refrigerating blower 35 is driven, the air in the vegetable compartment 4 is sucked into the refrigerating blower 35 side from the suction port 43 and is sucked in, mainly as shown by the white arrows in FIG. The air is blown out to the blower duct 42 side. The air blown to the air duct 42 side passes through the cold air duct 34 (refrigerating cooler chamber 36 and the cold air supply duct 37), and is blown into the refrigerating chamber 3 from the plurality of cold air supply ports 39. The air blown out into the refrigerating chamber 3 is also supplied into the vegetable compartment 4 through the communication port 44, and is finally sucked into the refrigerating blower 35 for circulation. In this process, the air passing through the refrigerating cooler chamber 36 comes into contact with the refrigerating cooler 24 and is cooled to become cold air, and the cold air is supplied to the refrigerating chamber 3 and the vegetable compartment 4 to form the refrigerating chamber 3 and The vegetable compartment 4 is cooled to a temperature in the refrigerating temperature zone.

As shown in FIGS. 2 and 4, the cold air duct 34 is located on the front side of the refrigerating cooler chamber 36 on the right side when viewed from the front and behind the chilled chamber 14, and is a dedicated duct for mist. 45 is provided so as to be removable. As shown in FIGS. 5 to 8, the dedicated duct 45 for mist is formed by the front wall 36a of the refrigerating cooler chamber 36 and the duct constituent member 46 mounted on the front surface of the refrigerating cooler chamber 36. The duct constituent member 46 forming the dedicated mist duct 45 is removable from the front wall 36a. In this case, the dedicated mist duct 45 is formed in a flat rectangular box shape that is long in the left-right direction along the front wall 36a and has a small depth dimension in the front-rear direction. The main body of the electrostatic atomizer 48 constituting the mist discharging means for discharging the mist is housed in the dedicated mist duct 45. Hereinafter, the electrostatic atomizer 48 will be described in detail.

As shown in FIG. 9, the electrostatic atomizer 48 includes a mist generation unit 51 having a mist discharge unit 50 and a power supply device (transformer) 52 for applying a negative high voltage to the mist discharge unit 50. It is configured in preparation. The mist generation unit 51 includes a water supply unit 53 that supplies water to the mist discharge unit 50. The water supply portion 53 has a horizontal portion 53a extending in the left-right direction and a vertical portion 53b extending downward from the right end portion of the horizontal portion 53a, and has an inverted L-shape when viewed from the front, and has an L-shape. The water-retaining material 55 is housed in the eggplant case 54. Therefore, the water supply section 53 has a refraction section 53c between the horizontal section 53a and the vertical section 53b. The horizontal portion 53a and the vertical portion 53b of the water supply portion 53 are arranged along the front wall 36a so as to be parallel to the front wall 36a of the refrigerating cooler chamber 36 in the cold air duct 34.

The water-retaining material 55 is, for example, a felt-like material entwined with fibers, has excellent water absorption and water retention, and sucks up water (defrosted water) stored in a water storage container 56, which will be described later, by a capillary phenomenon. The water retention material 55 may be a continuous foam as long as water can be sucked up by a capillary phenomenon. The horizontal portion 53a of the water supply portion 53 is arranged slightly to the right in the dedicated mist duct 45, and the lower end portion of the vertical portion 53b is the lower part of the duct constituent member 46 and the refrigerating cooler chamber as shown in FIG. It is inserted into the lower front portion in the refrigerating cooler chamber 36 through the hole formed in the step portion 36b at the front portion of the 36. The outer circumference of the water retaining material 55 is covered with a case 54. In the water retaining material 55, the portion of the horizontal portion 53a and the portion of the vertical portion 53b may be formed of separate members. The water retention material 55 constitutes a water supply member that transfers water from the water storage container 56 to the mist discharge unit 50.

A water storage container 56 (see FIG. 8) constituting the water storage unit is provided in the front portion of the lower portion of the refrigerator chamber 36 for refrigeration. The water storage container 56 is located between the refrigerating cooler 24 and the drainage gutter 40 located below the water storage container 56, and is located below the water supply unit 53, and the front portion thereof expands downward of the refrigerating cooler chamber 36. By attaching to the protruding portion 36c, it is provided in a cantilevered state so as to project rearward. In this case, the lower bulging portion 36c to which the front portion of the water storage container 56 is attached is below the front wall 36a and bulges (protrudes) forward from the front wall 36a. Assuming that the front wall 36a is the first bulge, the lower bulge 36c is the second bulge that protrudes forward. The water storage container 56 is separated from the refrigerating cooler 24 and the inner box 2b forming the rear surface of the refrigerating cooler chamber 36 in a state of being attached to the lower bulging portion 36c. The refrigerating cooler 24 is in contact with the inner box 2b forming the rear surface of the refrigerating cooler chamber 36.

The lower end of the vertical portion 53b in the water supply portion 53 penetrates a hole formed in the lower portion of the duct constituent member 46 and the step portion 36b in the front portion of the refrigerating cooler chamber 36, and is upward in the water storage container 56. It is inserted from. The water storage container 56 receives and stores the defrosted water dripping from the refrigerating cooler 24. As described above, the water retention material 55 of the water supply unit 53 sucks up the water (defrosted water) stored in the water storage container 56 by the capillary phenomenon and supplies it to the mist discharge unit 50.

An overflow portion 56a set lower than the others is formed in the upper part of the tip portion on the rear side of the water storage container 56, and when the water stored in the water storage container 56 overflows, the overflow portion 56a is used. It will overflow. The overflow portion 56a is located above the drainage gutter 40, and the water overflowing from the overflow portion 56a is received by the drainage gutter 40 and discharged to the defrosted water evaporating dish 28 outside the machine. Become.

A mist discharging portion 50 is provided in the horizontal portion 53a of the water supply portion 53. The mist discharging portion 50 is composed of a plurality of mist discharging pins 57, each of which constitutes a protrusion. A plurality of mist discharge pins 57 are arranged upward on the upper side of the horizontal portion 53a, in this case, four of them are arranged in a horizontal row in the left-right direction and are arranged apart from each other, and on the lower side of the horizontal portion 53a. A plurality of them are arranged downward in a horizontal row in the left-right direction, and in this case, four of them are arranged apart from each other. Therefore, the mist discharge portion 50 is composed of a plurality of mist discharge pins (protrusions) 57 that project in different directions (upper and lower). Further, the mist discharge portion 50 is arranged such that a plurality of mist discharge pins (protrusions) 57 extend in opposite directions in the vertical direction with the horizontal portion 53a in the water supply portion 53 in between. Further, the plurality of mist discharge pins (protrusions) 57 are arranged in two upper and lower stages. Each mist discharge pin 57 is arranged along the front wall 36a of the refrigerating cooler chamber 36 in the cold air duct 34 so as to be parallel to the front wall 36a. The mist discharge section 50 is provided at a position adjacent to the vegetable compartment 4 in the lower rear portion of the refrigerating chamber 3, and is arranged behind the chilled chamber 14.

Each mist discharge pin 57 is formed into a pin shape (rod shape) by mixing and twisting polyester fiber and carbon fiber as a conductive substance, for example, and has water retention and water suction characteristics, and is conductive. have. Platinum nanocolloids are supported on each mist release pin 57. The platinum nanocolloid can be supported, for example, by immersing the mist release pin 57 in a treatment liquid containing the platinum nanocolloid and firing the mist release pin 57. Each mist discharge pin 57 has a base end portion penetrating the case 54 in the water supply portion 53 and contacting the water retention material 55. At the left end of the horizontal portion 53a of the water supply portion 53, a power receiving pin 58 constituting a power receiving electrode is provided so as to project to the left. The base end portion of the power receiving pin 58 is in contact with the water retaining material 55 in the case 54.

The power supply device 52 is provided in a fixed state so as to be located on the left side of the mist generation unit 51 in the mist dedicated duct 45. A power supply terminal 61 made of a faston terminal to which a lead wire 60 is connected is provided at the right end of the power supply device 52, and the power receiving pin 58 of the mist generation unit 51 is connected to the power supply terminal 61. There is.

As is well known, the power supply device 52 includes a rectifying circuit including a high-voltage transformer that converts a high-voltage power supply (AC power supply) into direct current, a booster circuit, and the like, and generates a negative high voltage (for example, -6 kV). , The power is output to the power receiving pin 58 via the power supply terminal 61.

As a result, a negative high voltage from the power supply device 52 is applied from the power receiving pin 58 to each mist discharge pin 57 via the water content of the water retention material 55, and each mist discharge pin 57 is negatively charged. There is. Further, in this case, the outer box 2a of the refrigerator body 1 is grounded via a ground wire (not shown) or the like.

In the electrostatic atomizer 48 configured as described above, in a state where the water in the water storage container 56 is sucked up by the water retention material 55 and supplied to each mist discharge pin 57, the power supply device 52 is supplied to each mist discharge pin 57. Negative high voltage from is applied. At this time, electric charges are concentrated on the tip of each mist discharge pin 57, and energy exceeding the surface tension is given to the water contained in the tip. As a result, the water at the tip of each mist discharge pin 57 splits (Rayleigh split) and is discharged from the tip in the form of fine mist (electrostatic atomization phenomenon). Here, the water particles released in the form of mist are negatively charged and contain hydroxyl radicals generated by the energy.

Therefore, hydroxyl radicals having a strong oxidizing action are released from each mist release pin 57 together with the mist, and the action of the hydroxyl radicals enables sterilization and deodorization. In this case, the counter electrode corresponding to the negatively charged mist discharge pin 57 is not provided. Therefore, the discharge itself from the mist discharge pin 57 becomes very gentle, and no harmful gas (ozone or the ozone thereof oxidizes nitrogen in the air) without causing a corona discharge between the discharge electrode and the counter electrode. It is possible to suppress the generation of nitrogen oxides, nitrite, nitric acid, etc. generated by.

Here, the mist release pin 57 (mist release unit 50) can be said to be a sterilizing component releasing means (also a deodorizing component releasing means) that releases a sterilizing component (also a deodorizing component) called hydroxyl radical, and is electrostatic. The atomizing device 48 can be said to be a sterilizing component generating means (deodorizing component generating means).

A wind supply port 62a (see FIGS. 4 and 6) is provided on the front wall 36a of the refrigerating cooler chamber 36 constituting the rear wall of the dedicated mist duct 45. Two wind supply ports 62a are arranged one above the other so as to face the upper and lower mist discharge portions 50 (mist discharge pins 57). Each wind supply port 62a is formed in a horizontally long rectangular shape. A ventilation passage 62b (see FIG. 6) is provided behind the wind supply port 62a. As shown in FIG. 6, the ventilation passage 62b is formed so as to extend in the vertical direction in the front portion of the heat insulating material 38, the lower end portion is opened to communicate with the inside of the refrigerating cooler chamber 36, and the upper portion is formed. The air supply port 62a communicates with the mist dedicated duct 45. Therefore, when the refrigerating blower 35 is driven, most of the air blown from the air duct 42 to the refrigerating cooler chamber 36 side flows to the upper cold air supply duct 37 side through the refrigerating cooler 24. The air in the section does not pass through the refrigerating cooler 24, but passes through the ventilation passage 62b from the front side of the refrigerating cooler 24, and is supplied into the mist dedicated duct 45 from the two air supply ports 62a. (See arrow A1 in FIG. 6). The air supplied from the wind supply port 62a into the mist dedicated duct 45 comes to convection in the mist dedicated duct 45.

Above the power supply device 52, a mist duct 63 (see FIGS. 4 and 7) for the refrigerating chamber, which is located behind the front wall 36a of the refrigerating cooler chamber 36 and extends upward, is provided. The lower end of the refrigerating chamber mist duct 63 opens in the mist dedicated duct 45 to serve as a refrigerating chamber mist outlet 63a, and the upper end thereof communicates with the cold air supply duct 37 in the cold air duct 34. .. Therefore, a part of the mist generated in the dedicated mist duct 45 passes from the refrigerating room mist outlet 63a through the refrigerating room mist duct 63 and the cold air supply duct 37, and from the cold air supply port 39 into the refrigerating room 3. It is designed to be supplied (see arrow B1 in FIGS. 4 and 7).

A mist outlet 65 for a chilled chamber (see FIGS. 4 and 7) is located above the power supply device 52 on the front surface (position different from the upper surface) of the duct component 46 in the dedicated duct 45 for mist. A part of the mist is supplied into the chilled chamber 14 from the chilled chamber mist outlet 65 (see arrows B2 in FIGS. 4 and 7). Further, on the front surface of the duct constituent member 46, an egg case mist outlet 66 (see FIG. 4) is provided located on the left side of the chilled chamber mist outlet 65, and the egg case mist outlet 66 is provided. A part of the mist is also supplied from 66 to the inside of the egg case 15 (see arrow B3 in FIG. 4).

Further, as shown in FIG. 5, a mist outlet 67 for a vegetable compartment is provided in the lower part on the right side of the dedicated mist duct 45. The vegetable room mist outlet 67 communicates with the communication port 44, and a part of the mist in the mist dedicated duct 45 enters the vegetable room 4 through the vegetable room mist outlet 67 and the communication port 44. Is also being supplied.

A chilled chamber cold air supply port 68 (see FIGS. 4, 6, and 8) is provided above the mist dedicated duct 45 so as to be located above the mist discharge unit 50. As shown in FIG. 8, the chilled chamber cold air supply port 68 has a rear portion that penetrates the heat insulating material 38 and communicates with the refrigerating cooler chamber 36, and a front portion that penetrates the mist dedicated duct 45 and penetrates the chilled chamber. It communicates with 14. Therefore, a part of the cold air immediately after passing through the refrigerating cooler 24 of the refrigerating cooler chamber 36 is directly supplied to the chilled chamber 14 through the chilled chamber cold air supply port 68 (FIG. 6). , Refer to arrow A2 in FIG. 8), the temperature of the chilled chamber 14 is maintained at about 0 ° C. by the cold air. The heat insulating material 38 also serves as an insulating means between the refrigerating cooler 24 and the mist discharging portion 50.

Next, the operation of the above configuration will be described. As described above, when cooling the refrigerating chamber 3 and the vegetable compartment 4, the cold air cooled by the refrigerating cooler 24 (the cold air after passing through the refrigerating cooler 24) acts as a blower for the refrigerating blower 35. As shown by the white arrow mainly in FIG. 1, the air is supplied into the refrigerating room 3 from a plurality of cold air supply ports 39 through the cold air supply duct 37, and a part of the air is supplied from the cold air supply port 68 for the chilled room. It is supplied directly into the chilled chamber 14 (see arrow A2 in FIGS. 6 and 8). The cold air supplied to the refrigerating chamber 3 and the chilled chamber 14 contributes to cooling the stored foods and the like, then merges and is also supplied to the vegetable chamber 4 from the communication port 44. The cold air supplied into the vegetable compartment 4 contributes to the cooling of the stored vegetables and the like, then is sucked into the refrigerating blower 35 side from the suction port 43, and is cooled again by the refrigerating cooler 24, repeating the circulation. ..

Further, when the refrigerating chamber 3 and the vegetable compartment 4 are cooled, a part of the air flowing in the refrigerating cooler chamber 36 before passing through the refrigerating cooler 24 is indicated by an arrow A1 in FIG. As described above, the air is supplied into the mist dedicated duct 45 from the two air supply ports 62a through the ventilation passage 62b. The air supplied into the dedicated mist duct 45 collides with the mist discharging portion 50 (mist discharging pin 57) of the mist generating unit 51 and the inner surface of the duct constituent member 46, and convects and diffuses in the dedicated mist duct 45. To go.

At this time, when the electrostatic atomizer 48 is driven, fine mist containing hydroxyl radicals is discharged from each of the plurality of mist discharge pins 57 in the mist generation unit 51. As shown by the arrow B1 in FIG. 7, a part of the mist discharged from the mist discharge pin 57 rides on the air convected in the mist dedicated duct 45 and is a mist for the refrigerating room from the mist outlet 63a for the refrigerating room. It is supplied into the refrigerating chamber 3 from the cold air supply port 39 through the duct 63 and the cold air supply duct 37.

Further, a part of the mist discharged from the mist discharge pin 57 is supplied into the chilled chamber 14 from the mist outlet 65 for the chilled chamber as shown by the arrow B2 in FIGS. 4 and 7, and is shown in FIG. As shown by the arrow B3, it is also supplied into the egg case 15 from the egg case mist outlet 66. Further, a part of the mist discharged from the mist discharge pin 57 is also supplied into the vegetable compartment 4 from the vegetable compartment mist outlet 67 at the lower right through the communication port 44.

Therefore, in the present embodiment, the mist generated in the dedicated mist duct 45 can be supplied to a plurality of supply destinations such as the refrigerating room 3, the chilled room 14, the egg case 15, and the vegetable room 4. In addition to being expected to have the effects of sterilizing and deodorizing the supply destination, it can also be expected to moisturize and maintain the freshness of vegetables and the like.

According to the above-mentioned first embodiment, the following effects can be obtained.
An electrostatic atomizer 48 (mist discharging means) for discharging mist from the mist discharging unit 50 is provided. A part of the air before passing through the refrigerating cooler 24 (the wind supplied from the wind supply port 62a into the mist dedicated duct 45) circulated by the refrigerating blower 35 is supplied to the mist discharging unit 50. The mist discharged from the mist discharging unit 50 together with the air is configured to be supplied to the refrigerating room 3, the chilled room 14, and the vegetable room 4, which respectively constitute the storage room. Here, among the air circulated by the refrigerating blower 35 as the air for supplying the mist discharged from the mist discharging unit 50 to each storage chamber, before passing through the refrigerating cooler 24, that is, the refrigerating cooler 24 Since the relatively warm air before being cooled by the refrigerator is used, unlike the case where the relatively low temperature air immediately after passing through the refrigerating cooler 24 is used, the air for supplying the mist is used. It is possible to prevent the storage room, particularly the vegetable room 4, from becoming too cold. Further, since the air (wind) supplied to the mist discharging unit 50 is the air before passing through the refrigerating cooler 24, that is, before being cooled by the refrigerating cooler 24 as described above, the mist is discharged by the air. It is also possible to prevent the portion 50 from freezing.

The refrigerating cooler 24 is arranged in the refrigerating cooler chamber 36 in the cold air duct 34 through which the air circulated by the refrigerating blower 35 passes, and the mist discharging unit 50 is a dedicated mist duct outside the cold air duct 34. It is arranged in 45. The front wall 36a of the refrigerating cooler chamber 36 in the cold air duct 34 is provided with an air supply port 62a for supplying air on the upstream side of the refrigerating cooler 24 to the mist discharging section 50. According to this configuration, the mist discharge unit 50 is arranged outside the cold air duct 34 in which the refrigerating cooler 24 is arranged, and the mist discharged from the mist discharging unit 50 is not supplied to the refrigerating cooler 24. Therefore, the occurrence of mist freezing can be prevented.

The cold air duct 34 has a front wall 36a (first bulge) of the refrigerating cooler chamber 36 in which the refrigerating cooler 24 is arranged, and a water storage container 56 below the front wall 36a. The wind supply port 62a, which has a lower bulging portion 36c (second bulging portion) and supplies wind to the mist discharging portion 50, is provided on the front wall 36a which is the first bulging portion. There is. According to this configuration, the water storage container 56 is arranged in the cold air duct 34, and the water supplied from the air supply port 62a to the mist discharge unit 50 is not supplied to the water storage container 56, so that the water storage container 56 is stored in the water storage container 56. Water is hard to evaporate, and water for mist can be secured well.

The lower bulging portion 36c, which is the second bulging portion, is provided so as to project significantly forward from the front wall 36a, which is the first bulging portion, and constitutes an electrostatic atomizing device constituting the mist discharging means. 48 has a water retaining material (water supply member) 55 that transfers water from the water storage container 56 to the mist discharging portion 50, and the water retaining material 55 is contained in a dedicated mist duct 45 outside the cold air duct 34 from the lower bulging portion 36c. The extended mist discharging portion 50 is arranged in front of the front wall 36a. According to this configuration, the wind supply port 62a for supplying wind to the mist discharge portion 50 is formed on the front wall 36a, and the wind supplied from the wind supply port 62a into the dedicated mist duct 45 is. Since it does not hit the lower part of the water-retaining material 55 that sucks up the water of the water storage container 56, it is possible to prevent the lower part of the water-retaining material 55 from drying by the wind from the wind supply port 62a, and the water of the water storage container 56 is sent to the mist discharge part 50. Water can be supplied well. Moreover, since the water-retaining material 55 is covered with the case 54, the water-retaining material 55 is difficult to dry even if the case 54 receives wind.

The chilled chamber 14 is provided with a chilled chamber cold air supply port 68 that directly supplies a part of the air (cold air) immediately after passing through the refrigerating cooler 24 to the chilled chamber 14 in the mist dedicated duct 45. The cold air supplied from the cold air supply port 68 for the chilled chamber can be cooled to a temperature lower than that of the refrigerating chamber 3 and the vegetable compartment 4, and the temperature of the chilled chamber 14 can be maintained at about 0 ° C.

The electrostatic atomizer 48 constituting the mist discharging means includes a mist discharging unit 50 that discharges mist, a water supply unit 53 that supplies water to the mist discharging unit 50, and a power supply that applies a negative voltage to the mist discharging unit 50. A device 52 is provided, and the mist discharge unit 50 is composed of a plurality of mist discharge pins (protrusions) 57 that project in different directions. With this configuration, unlike the case where the protrusion direction for generating mist is only one direction, the supply direction of mist can be set to a plurality of directions, and the supply range of mist can be widened.

The mist discharge portion 50 is configured such that the mist discharge pin (protrusion) 57 extends in the opposite direction vertically with the horizontal portion 53a of the water supply portion 53 in between, so that the mist can be discharged in the opposite directions of the upper and lower sides. , The supply range of mist can be widened. Further, the horizontal portion 53a of the water supply portion 53 and each mist discharge pin 57 are arranged along the front wall 36a so as to be parallel to the front wall 36a of the refrigerating cooler chamber 36 in the cold air duct 34. , It is possible to reduce the thickness in the front-back direction. By arranging the mist discharge pins (protrusions) 57 in two upper and lower stages, compactness becomes possible.

The mist discharging unit 50 has a configuration in which a plurality of the mist discharging pins (protrusions) 57 are arranged side by side in a row, so that the amount of mist discharged can be increased and the mist supply range can be further widened. It can be made thinner, and it can be made thinner.

The water supply unit 53 has a refraction unit 53c, and a water storage container 56 for storing water is provided below the refraction unit 53c, and the water stored in the water storage container 56 can be supplied to the refraction unit 53c. It was configured. As a result, the water in the water storage container 56 can be supplied to the mist discharge pin 57 via the refracting portion 53c. Further, the mist discharge pin 57 can be separated from the water storage container 56. The power supply device 52 is arranged on the opposite side of the refracting portion 53c with the mist discharging portion 50 in between. This makes it possible to further separate the power supply device 52 from the water storage container 56.

Further, the power supply device 52 and the mist generation unit 51 are arranged along the front wall 36a of the refrigerating cooler chamber 36 in the cold air duct 34 so as to be parallel to the front wall 36a, whereby electrostatic atomization is performed. The device 48 can be made thinner in the depth direction.

Since the water supplied to the mist discharge pin 57 uses the defrosted water of the refrigerating cooler 24 stored in the water storage container 56, the water can be automatically supplied to the water storage container 56, and the user can use it. You can save the trouble of supplying water.

The electrostatic atomizer 48 constituting the mist discharge means is installed in the refrigerator main body 1, and the mist discharge pin (protrusion) 57 in the mist discharge portion 50 of the electrostatic atomizer 48 is aligned with the cold air duct 34. Placed in. As a result, the depth dimension of the electrostatic atomizer 48 in the front-rear direction can be suppressed, and the thickness can be reduced. Along with this, it becomes possible to suppress a decrease in the internal volume. Further, the mist discharge pin (protrusion) 57 can be arranged in the mist dedicated duct 45, or can be arranged in the refrigerating room 3 or the vegetable room 4 without using the mist dedicated duct 45. become.

The refrigerator main body 1 is provided with a dedicated mist duct 45 for accommodating an electrostatic atomizer 48 having a mist discharging unit 50, and if the supply destination of the mist generated by the mist discharging unit 50 is different in the dedicated mist duct 45. Multiple mist outlets are provided. Specifically, the plurality of mist outlets are a refrigerator chamber mist outlet 63a, a chilled chamber mist outlet 65, an egg case mist outlet 66, and a vegetable chamber mist outlet 67. As a result, the mist generated in the dedicated mist duct 45 can be supplied to the four supply destinations of the refrigerating room 3, the chilled room 14, the egg case 15, and the vegetable room 4, and the mist supply range is widened. And the range of effect of the mist can be expanded. Of the mist supply destinations, the chilled chamber 14, the egg case 15, and the vegetable chamber 4 have a chilled case 18, an egg case 15, and a vegetable case (lower case 11, upper case 12), respectively, and the mist is stored in these cases. It can be supplied well.

In this case, the plurality of mist outlets (mist outlet 63a for the refrigerator compartment, mist outlet 65 for the chilled chamber, mist outlet 66 for the egg case, and mist outlet 67 for the vegetable chamber) are the mist discharge portions 50. Since it is arranged around the center of the mist, the mist discharged from the mist discharge unit 50 can be satisfactorily supplied to each mist outlet.

The mist generation unit 51 has a mist discharge pin (protrusion) 57, and the plurality of mist outlets (mist outlet 63a for a refrigerating chamber, mist outlet 65 for a chilled chamber, and an egg) of the dedicated duct 45 for the mist. The mist outlet 66 for the case and the mist outlet 67) for the vegetable compartment are arranged at positions different from the positions facing the mist discharge pin 57. Even if a finger or a foreign substance is inserted into the 45, it is possible to prevent them from directly touching the mist discharge pin 57, and safety can be ensured.
Further, since the duct constituent member 46 forming the dedicated duct 45 for mist is removable, maintenance of the mist generation unit 71 and the like can be easily performed.

(Second Embodiment)
10 to 12 show a second embodiment. In this second embodiment, the configuration of the wind supply port is different from that of the first embodiment.
In the front wall 36a of the refrigerating cooler chamber 36 constituting the rear wall of the dedicated mist duct 45, one wind supply port 70 is provided so as to be located behind the horizontal portion 53a of the water supply portion 53. The wind supply port 70 is formed in a rectangular shape having a larger vertical dimension than the one wind supply port 62a of the first embodiment and larger than the vertical dimension of the horizontal portion 53a, and the rear portion thereof has a rear portion. It communicates with the ventilation passage 62b of the heat insulating material 38. A wind separation portion 71 having a mountain-shaped cross section is provided on the rear surface of the horizontal portion 53a of the water supply portion 53.

In this configuration, the air flowing upward through the ventilation passage 62b is supplied from the wind supply port 70 into the mist dedicated duct 45 (see arrow A3 in FIG. 11). At this time, the air (wind) supplied into the dedicated mist duct 45 is divided into upper and lower parts by the wind separation part 71, and easily hits the upper and lower mist discharge parts 50 (mist discharge pin 57), and the mist discharge part The mist released from 50 is easily diffused.
Even in the second embodiment having such a configuration, the same effects as those in the first embodiment can be obtained.

(Third Embodiment)
FIG. 13 shows a third embodiment. In this third embodiment, the configuration of the mist generation unit 76 in the electrostatic atomizer 75 constituting the mist discharging means is different from that of the first embodiment.
The mist generation unit 76 includes a mist discharge unit 77 and a water supply unit 78 that supplies water to the mist discharge unit 77. The water supply portion 78 has a circular portion 78a forming a circle when viewed from the front and a vertical portion 78b extending downward from the circular portion 78a, and the water retention material 55 similar to that of the first embodiment is provided in the case 79. It is housed and configured. The lower end portion of the vertical portion 78b is provided in the refrigerating cooler chamber 36 through a hole in the lower part of the duct constituent member 46 and the stepped portion 36b (see FIG. 8) at the front portion of the refrigerating cooler chamber 36. It is inserted into the water storage container 56 from above. The circular portion 78a and the vertical portion 78b in the water supply portion 78 are arranged along the front wall 36a so as to be parallel to the front wall 36a of the refrigerating cooler chamber 36 in the cold air duct 34.

The mist discharge unit 77 is composed of a plurality of mist discharge pins 57, each of which constitutes a protrusion. The mist discharge pins 57 are radially provided on the outer peripheral portion of the circular portion 78a. Therefore, the mist discharge portion 77 is composed of a plurality of mist discharge pins 57 (protrusions) that project in different directions. The base end of each mist discharge pin 57 penetrates the case 79 and is in contact with the water retention material 55. Each mist discharge pin 57 is also arranged along the front wall 36a so as to be parallel to the front wall 36a of the refrigerating cooler chamber 36 in the cold air duct 34.

A protruding portion 78c projecting to the left is provided on the left portion of the circular portion 78a of the water supply portion 78, and the power receiving pin 58 is provided on the protruding portion 78c in a state of projecting to the left. The power receiving pin 58 is connected to the power supply terminal 61 on the power supply device 52 side. The air supply port 62a for supplying air to the inside of the mist dedicated duct 45 (mist discharge portion 72) is located on the front wall 36a of the refrigerating cooler chamber 36, and is located above and below the circular portion 78a of the water supply portion 78. Two pieces are formed at the top and bottom so as to correspond to.

In this configuration, the water stored in the water storage container 56 is sucked up by the water retention material 55 and supplied to each mist discharge pin 57. Further, a negative high voltage from the power supply device 52 is applied from the power receiving pin 58 to each mist discharge pin 57 via the moisture of the water retention material 55, and based on this, fine mist is discharged from each mist discharge pin 57. Will be done. Similar to the first embodiment, the mist discharged from each mist discharge pin 57 rides on the wind supplied from the wind supply port 62a into the mist dedicated duct 45, and has a plurality of mist outlets (refrigerator room mist). Multiple supply destinations such as a refrigerating room 3, a chilled room 14, an egg case 15, and a vegetable room 4 from an outlet 63a, a mist outlet 65 for a chilled room, a mist outlet 66 for an egg case, and a mist outlet 67 for a vegetable room). Will be supplied to.

In such a third embodiment, in particular, since the mist discharge pins 57 are arranged radially, there is an advantage that the mist can be discharged in more directions than in the case of the first embodiment.

(Other embodiments)
The mist discharging means is not limited to the electrostatic atomizing device. For example, an ultrasonic atomizing device that atomizes the water stored in the water storage unit by the ultrasonic vibration of the ultrasonic vibrator to discharge the mist. May be used.

Further, as the mist outlet for blowing out the mist released from the mist discharging means, the mist outlet 63a for the refrigerator compartment and the mist outlet 66 for the egg case may not be provided.
As described above, according to the refrigerator of the present embodiment, the mist discharged from the mist discharging part is supplied to the storage chamber by using the air air before passing through the cooler, so that the storage chamber becomes too cold. , It is possible to prevent the mist discharging portion from freezing.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

In the drawing, 1 is the refrigerator body, 3 is the refrigerating room (storage room), 4 is the vegetable room (storage room), 14 is the chilled room (storage room), 24 is the refrigerating cooler (cooler), and 29 is. Control device, 34 is a cold air duct, 35 is a refrigerating blower (blower), 36 is a refrigerating cooler room, 36a is a front wall (first bulge), 36c is a lower bulge (second bulge). Outlet), 37 is a cold air supply duct, 39 is a cold air supply port, 45 is a dedicated duct for mist, 48 is an electrostatic atomizer (mist discharge means), 50 is a mist discharge part, 51 is a mist generation unit, 52 is. Power supply device, 53 is a water supply unit, 55 is a water retention material (water supply member), 56 is a water storage container (water storage unit), 57 is a mist discharge pin, 62a is a wind supply port, 62b is a ventilation passage, 63 is for a mist for a refrigerator. Duct, 63a is a mist outlet for a refrigerator, 65 is a mist outlet for a chilled room, 66 is a mist outlet for an egg case, 67 is a mist outlet for a vegetable room, 68 is a cold air supply port for a chilled room, and 70 is a wind. A supply port, 75 is an electrostatic atomizer (mist discharging means), 76 is a mist generating unit, 77 is a mist discharging unit, and 78 is a water supply unit.

Claims (2)

The heat insulating box that makes up the refrigerator body and
A partition plate that divides the inside of the heat insulating box into a plurality of storage chambers,
With a heat insulating material that has higher heat insulating properties than the partition plate,
A cooler for cooling the storage chamber and
Mist release means to release mist,
Equipped with
The cooler is provided above the mist discharging means and is provided.
The heat insulating material does not hold the mist discharging means, is provided between the cooler and the mist discharging means, and is separated from the mist discharging means, and the heat insulating material is described. The heat insulating material is provided at a position on the back surface side of the heat insulating box in the area where the mist discharging means is provided, and the heat insulating material is separated from the mist discharging means by the heat insulating material in the cooler. Refrigerator longer than the distance away from. The refrigerator according to claim 1, wherein the mist discharging means is capable of discharging mist downward.

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