JP3469757B2 - refrigerator - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [0001] BACKGROUND OF THE INVENTION 1. Field of the Invention
By partitioning the inside of the heat box with partition walls,
And the upper and lower ice greenhouses and vegetable rooms,
The present invention relates to a refrigerator having a storage room. [0002] 2. Description of the Related Art Conventionally, this kind of refrigerator has been
No. 6-12301 (F25D23 / 00).
As well as configuring a freezing room and a refrigerated room inside the heat insulation box,
Coolers and blowers are installed in the cooling chamber defined in the back of the freezing room.
The cooler cooled by this cooler is installed by a blower.
The system is supplied to each of the above chambers, circulated and cooled.
ing. In recent years, refrigeration has been
The refrigerator has a freezer compartment and a refrigerator compartment as well as a vegetable compartment and an ice compartment.
A compartment is formed, and in the vegetable room, vegetables that do not like drying are stored in containers
Cool indirectly in the greenhouse,
Keep perishable foods such as fish in an ice temperature range of 0 ° C to -3 ° C.
Cooling things are being developed. [0004] From such a situation, in a refrigerator room or an ice warm room,
Part of the cool air cooled by the cooler is directly
Cools by distributing and supplying.
Is controlled by adjusting the
The temperature inside the vegetable room is relatively high after circulating in the cold room or ice room.
The structure which circulates the cool air of high temperature is adopted. [0005] Here, the opening and closing of the heat insulating door and the input of a large amount of food are performed.
Load in the cold room or ice greenhouse increases
The temperature of the cold air supplied to the vegetable compartment also increased.
Therefore, it is impossible to secure the cooling capacity of the vegetable room.
You. Therefore, conventionally, part of the cold air supplied to the refrigerator compartment is
By adopting a duct configuration that distributes directly to the vegetable room,
This had been resolved. [0006] However, as described above,
Freezer room, ice room, refrigerator room and vegetable room
Usually, an ice greenhouse and a vegetable room should be constructed above and below the freezer room.
In both cases, the refrigerator compartment with the largest capacity is located above the ice greenhouse.
It will be configured at the top. That is, is the refrigerator compartment a cooler?
And the coolest wind that is supplied
It will also slow down. [0007] Therefore, as described above, the cooling air
Parts to be distributed to the vegetable compartment,
Cooling of the refrigerator compartment at the time of soaking or so-called pull-down after defrosting
There was a problem that the ability could not be secured. The present invention solves such a conventional technical problem.
The cooling capacity of the vegetable compartment was secured.
And effectively prevent a decrease in the cooling capacity of the refrigerator compartment
A refrigerator is provided. [0009] The refrigerator according to the present invention has a front surface.
Partitioning the interior of the heat-insulating box that opens into
More, the freezing room and the upper and lower ice greenhouses and vegetable room,
A refrigerator room above the greenhouse is formed, and at the back of the freezer room
Install a cooler and blower in the formed cooling room, and
More cool air is supplied to each room by a blower
Thing,The cold air circulated in the refrigerator compartment and the ice greenhouse
A vegetable compartment duct will be provided to the vegetable compartment, and a refrigerator compartment and
Supply cold air to the ice greenhouse inside the partition wall that partitions the ice greenhouse
Ice greenhouse duct and cold air to which cold air circulated in the refrigerator compartment flows
A refrigerator compartment suction duct is installed next to the refrigerator compartment suction duct.
Ice greenhouse duct
To communicate with the refrigerator compartment suction duct.
ToSome of the cold air supplied to the ice greenhouse is directly supplied.
It is. According to the present invention, a heat-insulating box that opens to the front surface
By partitioning the inside with partition walls,
The upper and lower ice greenhouses and the vegetable room, and the refrigerator room above the ice greenhouse
And a cooling chamber formed in the back of the freezing chamber.
A cooler and blower are installed, and the cool air cooled by the cooler
In a refrigerator that is supplied to each room with a blower
In the vegetable room, cool air circulating in the cold room and the ice green room is supplied to the vegetable room.
In addition to supplying via a duct, this vegetable compartment duct
Part of the cold air supplied to the ice greenhouse should be supplied directly.
Adversely affect the refrigerator compartment far from the cooler and the blower
Without affecting the cooling capacity of the vegetable compartment
become able to. [0011]Especially inside the partition that separates the refrigerator compartment and the ice compartment
ToAn ice greenhouse duct that supplies cold air to the ice greenhouse, and a refrigerator room
Refrigerator suction duct for cooling air circulating
At the same time, this refrigerator compartment suction duct is connected to the vegetable compartment duct.
And an ice greenhouse duct and a refrigerator compartment suction duct
The cold air supplied to the ice greenhouse.
A duct structure that supplies directly to the vegetable compartment duct is installed inside the partition wall
Consolidation is possible, greatly simplifying duct configuration
Reduced costs and improved cooling capacity
It is what becomes. [0012] BRIEF DESCRIPTION OF THE DRAWINGS FIG.
The form will be described in detail. FIG. 1 is a front view of a refrigerator according to the present invention, and FIG.
Is a front view of the refrigerator excluding the door, and FIG.
FIG. 4 is a front view of the refrigerator without the door, and FIG.
Fig. 5 is another vertical side view of the refrigerator.
FIG. 6 and FIG. 6 are still another longitudinal sectional side view of the refrigerator. The refrigerator 1 includes an outer box 2 made of a steel plate and an ABS or the like.
Insulation material such as polyurethane foam between inner boxes 3 made of hard resin
Insulated box with front opening, filled with foam 4 in place
6. The interior of the heat insulating box 6 is
The upper, lower and upper four chambers are provided by the cut wall 8, the middle partition wall 7 and the lower partition wall 9.
The upper part of the upper partition wall 8 is divided into a refrigerator compartment 11 and a lower partition.
The vegetable compartment 12, the upper partition 8 and the middle partition 7
Between the ice greenhouse 10 and the freezing room between the middle partition 7 and the lower partition 9
It is set to 13. Also, between the middle partition wall 7 and the lower partition wall 9
Is attached to the opening edge of
You. The opening of the front of the refrigerator compartment 11 is a double door.
When it is closed openably by the thermal insulation doors 14 and 14,
In both cases, the freezer compartment 13 and the vegetable compartment 12 are the container 1 with the top opening.
Insulated drawer door 1 with 6A, 17A, 18A
6, 17 (the freezing compartment 13 has these two upper and lower stages), 18
Each is openably closed. Ice greenhouse 10
Also a drawer-type insulated door with a container 19A with an open top
19 is openably and closably closed. The upper left corner of the freezer compartment 13 has an automatic ice making machine.
Machine 21 is installed. Furthermore, the interior of the freezer compartment 13 is
It is divided into front and rear by the cutting plate 22 and the cooler front plate 23, and is cooled.
A cooling chamber 24 is defined behind the front plate 23,
A cooler 26 is provided vertically in the cooling chamber 24. this
A blower 29 is provided above the center of the cooler 26.
The defrost heater 31 is provided below the cooler 26.
I have. The upper and central portions of the partition plate 22
A plurality of freezing chamber discharge ports 13A,.
The freezer inlets 13B, 13B are provided on the lower left and right sides of the cutting plate 22.
However, the freezer compartment suction port 1
3C and 13C are formed adjacent to each other. On the other hand, the cooler front plate 23 is located on the rear side of the partition plate 22.
Is provided at a small interval,
A grill 23A facing the fan 32 of the machine 29 is formed.
You. Between the partition plate 22 on the front side of the fan 32 and the cooler front plate 23
Are in communication with the freezer compartments 13A. Ma
In addition, an opening 23B is formed in the lower central portion of the cooler front plate 23.
The cooling chamber suction ports 13C, 13C and the cooling chamber 24
Is in communication with Also, the freezer inlets 13B, 13B
Communicates with the lowermost part of the cooling chamber 24 via the lower end of the cooler front plate 23
are doing. Here, the cooler 26 is shown in FIGS.
A plurality of sheets are provided at predetermined intervals as shown in FIG.
Aluminum fins 27 extending in the direction
And a refrigerant pipe 28 penetrating these fins 27.
A so-called plate fin type heat exchanger,
26, the fin density (pitch) at the lower end is sparse.
In addition, the fin density of the left and right front
I have. That is, the vertical dimension of each fin 27.
Two or three fins 27 are short in a row
The left and right fins 27 sandwiching the
In addition, the vertical dimension of the short fin 27 is shorter every other
Has become. Each fin 27 located on the left and right
The front and rear width is also narrowed every other sheet. Accordingly, the lower edge of the cooler 26 is
Area 26A of low density, and the area 26A
Standing up continuously from A,
Fin density region 26B extending to the bottom and
Right front and rear edges (fins extending in the vertical direction through which cool air flows)
The outer part of the cooler 26 where the edge of the
.. Are formed. Soshi
Therefore, it is assumed that the area 26B corresponds to the area below the blower 29.
The opening 23B corresponds to the front side of the region 26B.
(FIG. 8). Inserted into the partition wall 7 above the blower 29
Through the rear of the molded insulation material 38
A guide duct 39 is formed.
The lower part communicates with the space in front of the fan 32 and the upper part forms
The branch duct 42 formed in the heat insulating material 41 is connected and connected.
Have been. The branch duct 42 is provided with a refrigerator compartment bag.
Motor damper with full 43 and ice greenhouse baffle 44
-One through the refrigerator compartment duct 47 and the other through the
It is communicated with the ice greenhouse duct 48. And the refrigeration
The room baffle 43 is provided with ice at the entrance of the refrigerator compartment rear duct 47.
The greenhouse baffle 44 is located at the entrance of the ice greenhouse duct 48.
ing. The back of the inner box 3 is spaced from the back of the refrigerator compartment 11
The rear duct plate 49 is attached
The refrigerating room extending vertically between the surface duct plate 49 and the inner box 3
A rear duct 47 is formed. Of the rear duct plate 49
The refrigerator outlet 11A is formed on the front surface. Also,
A plurality of shelves 51 are provided in the refrigerator compartment 11.
Also, at the lower right corner of the rear duct plate 49 on the back of the refrigerator compartment 11
Is formed with a suction port 61 after the refrigerator compartment.
The suction port 61 is formed and heat-insulated on the rear side of the back plate 62 of the ice greenhouse 10.
Connected to the upper part of the return duct 63 formed on the side of the members 38, 41.
Through. Further, at the lower left corner of the refrigerator compartment 11, the automatic
A water supply tank 52 for supplying water to the ice machine 21 is housed therein.
ing. This water supply tank 52 is shown in FIGS.
The tank body 53 which is elongated in front and
A cover 54 for closing an upper surface opening of the tank body 53;
The cover 54 is attached to the cover 54 and the like.
Has been established. In this case, the front of the cover 54 has a rectangular shape.
A concave portion 54A is formed, and the bottom of the concave portion 54A is formed.
A rectangular injection port 57 is also formed on the surface. So
The lid member 56 has hinge portions 56A, 5A on both sides of the trailing edge.
6A is rotatably pivoted to the cover 54 behind the inlet 57.
Then, the inlet 57 is opened and closed. The lid member 56 has an inner surface shape of the concave portion 54A.
, So that the lid member
56 is designed so that fingers can be applied
You. Further, a water absorbing cylinder 54B is provided at the rear of the cover 54.
The water absorption cylinder 54B is lowered into the suction main body 53.
The rear end of the bar 54 is connected to the connecting portion 54C that opens rearward.
Through. When installing the water tank 52,
Water into the refrigerator compartment 11 and the water supply
The connecting portion 54C is detachably connected to the pipe 59. This
The water supply pipe 59 communicates with the automatic ice making machine 21.
And the water in the tank body 53 is sucked up from the water absorption cylinder 54B.
Automatic ice making via the connecting part 54C and the water supply pipe 59
The ice making operation is performed there. Generated
The ice collected is stored in the freezer 13. By the ice making operation, the tank body 53
When the water runs out, the water supply tank 52 is moved to the refrigerator compartment 11.
It is pulled out from inside, but in this case the concave lid
Insert your fingers into the material 56, hook it, and pull it forward
Thus, the water supply tank 52 can be easily pulled out. Then, the cover member 56 is turned upward from the front.
To open the injection port 57 and refill the tank body 53 with water.
However, also in this case, the lid member 56 can be easily opened.
Since it can be closed, the injection operation is also facilitated. Also, after refilling
The lid member 56 will be closed and carried. In this case,
The cover member 56 extends along the inner surface of the concave portion 54A of the cover 54.
Since the injection port 57 is closed (FIG. 1)
9), water leaks from the inlet 57 due to shaking during transport, etc.
It can also be prevented from being lost. On the other hand, the upper partition wall 8 is shown in FIGS.
As shown, an upper plate 66 and a lower plate 67 made of hard resin,
With the formed heat insulating material 68 provided along the lower surface of the plate 66
And between the molded heat insulating material 68 and the lower plate 67.
An ice greenhouse duct 48 is formed. Ice greenhouse duct 4
Reference numeral 8 denotes a blind alley-shaped partition wall 69 erected on the upper surface of the lower plate 67.
It is configured to expand forward from the rear entrance 48A.
The lower plate 67 located in the middle and front of the
A plurality of greenhouse discharge ports 71 are formed. The lower and right lower plates 67 in front of the partition 69
Are provided with partition walls 72 to 74,
Inside the upper partition wall 8 outside the ice greenhouse duct 48, two cold
The storage chamber suction ducts 77 and 78 are arranged side by side.
You. The front of the upper plate 66 has left and right suction ports in front of the refrigerator compartment.
79, 81 are formed, and the left refrigerator inlet 7 on the left side is formed.
9 is located at the inlet 77A of the refrigerator compartment suction duct 77 on the left side.
The right refrigerator inlet 81 is connected to the right refrigerator inlet duct.
The opening 78A communicates with the entrance 78A of the nest 78. Also,
The rear end of each refrigerator compartment suction duct 77, 78 is the return duct
63 and consequently to the vegetable compartment duct 87 described later.
Through. In this case, the left refrigerator compartment suction duct 77
The cross-sectional area of the passage is the cross-sectional area of the passage of the right refrigerator suction duct 78.
The suction portion 77A is also larger than the suction portion 7A.
8A (FIG. 15). Where each refrigerated
The chamber suction ducts 77 and 78 are from the front side of the ice greenhouse duct 48.
Since it is formed to bypass to the right side, the refrigerator compartment suction on the left side
The passage length of the duct 77 is the same as the passage length of the refrigerator compartment suction duct 78 on the right side.
It is longer than the road length. The width between the partition walls 72 and 69 is narrow.
A communication passage 83 is formed, and the communication passage 83
Suction of the front end of the ice greenhouse duct 48 and the refrigerator compartment suction duct 77
The portion 77A is in communication. And the back of the ice greenhouse 10
An ice greenhouse suction port 84 is formed on the right side of the face plate 62 so that a return
It is connected to the object 63. On the other hand, on the right side of the molded heat insulating material 38, a vegetable room
The upper end of the connecting member 86 is connected, and the right side of the cooling chamber 24 is
And a vegetable compartment duct 87 is formed inside it
are doing. The upper end of the vegetable compartment duct 87 is connected to the return duct.
And the lower end is in the upper right corner of the vegetable compartment 12.
It opens at the vegetable compartment discharge port 88. A vegetable compartment suction duct 91 is provided in the lower partition wall 9.
The vegetable room suction duct 91 is formed in the vegetable room 1
2, opened at the vegetable compartment suction opening 92 opened on the upper surface of the back,
In addition, it communicates with the lower end of the cooling chamber 24. The pre-partitioning member 15 is hard as shown in FIG.
Body 93 made of high-quality resin and a component provided in the body 93.
Shaped heat insulating material 94, front plate 96 made of steel plate, and
And a high-temperature refrigerant pipe 97 attached to prevent condensation.
The lower wall of the main body 93 has a lower front 93A and a lower rear 93B.
Has a stepped shape. The rear end of the front portion 93A has a lower surface.
At a slightly higher position than the rear 93B
And an engaging portion 93C protruding rearward is integrally formed.
You. The base of the seal member 98 is attached to the engagement portion 93C.
A portion 98A is engaged and attached from behind, and
The strip 98B projects forward and downward. The soft fin piece 98B of the sealing member 98 is
With the heat-insulating door 17 closed, the front side of the container 17A
Is sealed in close contact with the
The lower surface of the base 98A of the member 98 is
It is substantially flush with the lower surface. That is, the base of the sealing member 98
Part 98A or its mounting part (shape
Is not projected downward, so that the container 17A
Without being caught, the vertical dimension of the container 17A
It can be expanded to expand the effective volume. Incidentally, such a structure is provided on other partition walls 7, 8, and 9.
However, they are formed similarly. Also, 104
Is a refrigerator temperature sensor for detecting the temperature in the refrigerator 11
Yes, attached to the rear duct plate 49, 106 is ice temperature
An ice greenhouse temperature sensor for detecting the temperature in the room 10,
It is attached to the lower plate 67. Further, a machine room 99 is provided below the heat insulating box 6.
In the rear part of the machine room 99, the cooler is provided.
26 and a compressor 101 constituting a known refrigeration cycle
Condenser, machine room blower, etc. not shown are installed.
In addition, located below the heat insulating door 18 at the front end of the machine room 99.
The kick plate 102 is attached.
The back plate 102 is used to ventilate the inside of the machine room 99.
An intake port 103 is provided. With the above configuration, the compressor 101 and the blower 2
9 is operated, the cooling chamber 2 cooled by the cooler 26 is operated.
The cool air in 4 is sucked upward by fan 32 of blower 29
The freezer compartment 1 is raised from the freezer compartment discharge port 13A in the front.
3 is blown out. Then, the container 16 in the freezing room 13
A, after circulating through 17A and cooling, cool air is frozen at the bottom
From the chamber suction ports 13B, 13B, 13C, 13C to the cooling chamber 2
Return to 4 As a result, the freezing compartment 13 is cooled to a predetermined temperature.
It is maintained at the freezing temperature (about -20 ° C). The compressor 101
The operation of the blower 29 detects the temperature in the freezer 13.
It is controlled based on the freezer temperature sensor. Here, from the freezer compartment inlets 13B, 13B
The inflowing cool air is cooled from the area 26A at the lower end of the cooler 26.
Flows into the vessel 26 and rises between the fins 27.
However, the cold air flowing from the freezer compartment inlets 13C, 13C is cooled.
Region 26 slightly below the central part of the upper and lower sides of
B flows into the cooler 26. As will be described later, from the vegetable room suction duct 91
Circulating in the refrigerator compartment 11, the ice compartment 10 and the vegetable compartment 12
Humid cold air flows from the lower region 26A of the cooler 26
Due to the inflow, a large amount of frost is present in the area 26A of the cooler 26.
Adhesively grows, but flows in from freezer inlets 13C, 13C
The cooled air is supplied to the fins of the cooler 26 from above (downstream side).
Flows into the low-density area 26B, and then the fin density is high.
Since it is introduced into the area below the blower 29, the area 26B
Cooling air flowing from is distributed by the frost that has grown in the area 26A.
Is not disturbed. The left and right front and rear edges of the cooler 26 (cool air
The edge of the fin 27 extending vertically is located
Fin density low region 26
.. Are configured, the area 26A is temporarily frosty.
Even if it is blocked by growth, the area 26C
Frost blockage is delayed by the presence of Therefore, even in such a case, the cool air flows from the area 26C.
Can be introduced into the cooler 26 for heat exchange.
Heat exchange between the fins 27 and flowing cold air
To significantly improve the cooling capacity of the cooler 26
Will be able to The cooler 26 corresponding to the blower 29
The area 26C is formed on the left and right other than the center.
In the cooler 26, the filter in the portion where the cool air flows most
The density becomes higher as described above. Therefore, without frost
Can maintain frost efficiency while maintaining low heat exchange efficiency.
When it has grown, the above-mentioned region 26B or 26C
It is possible to maintain the flow of cold air and secure heat exchange
Become so. A part of the cool air blown from the blower 29 is
It flows into the guide duct 39 and is divided in two directions by the branch duct 42.
After being washed, one of the motor damper 46 has a refrigerator compartment bag.
It flows into the refrigerator compartment rear duct 47 via the full 43. Refrigerated
The cold air flowing into the room rear duct 47 is discharged from the refrigerator compartment outlet 11A.
... is blown out into the refrigerator compartment 11 and circulates inside.
After cooling, the suction port 61 after the refrigerator compartment and the suction port 7 before the refrigerator compartment
9 and 81. The other of the two divided by the branch duct 42
The ice temperature through the ice greenhouse baffle 44 of the motor damper 46
It flows into the chamber duct 48. Flowed into the ice greenhouse duct 48
Cold air blows into the ice greenhouse 10 from the ice greenhouse discharge port 71.
After circulating and cooling the inside, the ice greenhouse suction port 84
Inflow. The motor damper 46 is connected to the refrigerator compartment temperature sensor.
The baffle 43 is opened and closed based on the output of the
The inside of the storage room 11 is maintained at a refrigeration temperature of about + 5 ° C. Also ice
Baffle 44 based on the output of greenhouse temperature sensor 106
To open and close the container 19A in the ice greenhouse 10,
Maintain an ice temperature range of about -3 ° C. The above-mentioned refrigerating room rear suction port 61 and ice greenhouse suction port 8
The cool air that has flowed into 4 flows directly into the return duct 63
However, the cold air flowing from the inlets 79 and 81 in front of the refrigerator compartment
Returns through the refrigerator compartment suction ducts 77 and 78, respectively.
It flows into the return duct 63. Also, in the ice greenhouse duct 48
A part (a small amount) of the inflowing cold air passes through the ice greenhouse 10.
Through the communication passage 83 and directly into the refrigerator compartment suction duct 77
Into the air, merges with the cool air from the suction port 79, and returns
Flows into the port 63. Here, as described above, the left refrigerator compartment suction duct is used.
The passage length of the gate 77 is the passage length of the refrigerator compartment suction duct 78 on the right side.
It is longer than. Therefore, the same passage cross-sectional area and
In the area of the suction section, the flow path resistance of the refrigerator compartment suction duct 77 is refrigerated.
Because it is larger than the flow path resistance of the chamber suction duct 78, it is refrigerated.
The amount of cold air sucked from the front suction port 79 is the suction port in the refrigerator compartment.
It is smaller than the amount of cool air sucked from 81. The amount of the intake cold air is equal to the left of the refrigerator compartment 11.
If the right side is different, the cooling effect of the front of the refrigerator compartment 11 is
It is biased, and in the embodiment, the left is not cooler than the right
However, as described above, the passage of the refrigerator compartment suction duct 77 on the left side
The cross-sectional area of the road is determined by the cross-sectional area of the right refrigerator compartment suction duct 78.
The suction portion 77A is also wider than the suction portion 78A.
The ducts 77 and 78 have a flow path resistance.
The resistance is almost uniform. Therefore, the suction port in front of the refrigerator compartment
The amount of cold air flowing into the cooling chambers 79 and 81 is substantially uniform, and
The inside can be cooled uniformly. Next, the cool air flowing into the return duct 63
Flows into the vegetable compartment duct 87, descends there, and
It is discharged from the discharge port 88 into the vegetable compartment 12. And the field
Circulated in the vegetable room 12 and indirectly cooled the inside of the container 18A.
Later, it is sucked from the vegetable compartment 92 and formed in the lower partition wall 9.
Through the vegetable room suction duct 91 and the lowermost part in the cooling room 24
Return to. Then, as described above, the region 26 of the cooler 26
A flows again into A. As a result, the vegetables in the container 18A are dried.
Is kept at a temperature of about + 3 ° C to + 5 ° C in a state where
However, as described above, the return duct 63 is provided with the communication passage 8.
3 from the cold air, that is, through the ice greenhouse 10 and the refrigerator 11
Not low-temperature cold air (as it is cooled by the cooler 26)
Cold air) flows into the refrigerator compartment 11 or the ice warm compartment 10
When the load inside the machine increases and the cold air temperature rises
In addition, the cooling capacity in the vegetable compartment 12 will be secured.
You. The vegetable room 12 is supplied with the ice green room 10.
A part of the cold air to be supplied directly
Adversely affect the refrigerator compartment 11 which is far from the fan 26 and the blower 29
No reduction in cooling speed during pull-down
So that the cooling capacity of the vegetable compartment 12 can be secured.
become. Further, part of the cold air supplied to the ice greenhouse 10
The duct structure that directly supplies
Since it is concentrated in the cut wall 8, the duct configuration is extremely simple
To reduce costs and improve cooling capacity.
It becomes possible. [0056] As described in detail above, according to the present invention, the front surface
Partitioning the interior of the heat-insulating box that opens into
More, the freezing room and the upper and lower ice greenhouses and vegetable room,
A refrigerator room above the greenhouse is formed, and at the back of the freezer room
Install a cooler and blower in the formed cooling room, and
More cool air is supplied to each room by a blower
In the refrigerator, the vegetable compartment circulates through the refrigerator compartment and the ice compartment
While supplying the cooled air through the vegetable compartment duct,
Of the cold air supplied to the ice greenhouse
Because it is supplied directly, it is far from the cooler and the blower
The cooling capacity of the vegetable compartment without adversely affecting the refrigerator compartment
You will be able to secure power. [0057]Especially inside the partition that separates the refrigerator compartment and the ice compartment
ToAn ice greenhouse duct that supplies cold air to the ice greenhouse, and a refrigerator room
Refrigerator suction duct for cooling air circulating
At the same time, this refrigerator compartment suction duct is connected to the vegetable compartment duct.
And an ice greenhouse duct and a refrigerator compartment suction duct
The cold air supplied to the ice greenhouse.
A duct structure that supplies directly to the vegetable compartment duct is installed inside the partition wall
Consolidation is possible, greatly simplifying duct configuration
Reduced costs and improved cooling capacity
It is what becomes.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a front view of a refrigerator according to the present invention. FIG. 2 is a front view of the refrigerator of the present invention excluding a heat insulating door. FIG. 3 is a front view of the refrigerator excluding a heat insulating door from which a container and the like are removed. FIG. 4 is a vertical sectional side view of the refrigerator of the present invention. FIG. 5 is another longitudinal side view of the refrigerator of the present invention. FIG. 6 is still another longitudinal side view of the refrigerator of the present invention. FIG. 7 is a perspective view of a freezer compartment of the refrigerator according to the present invention. FIG. 8 is a transparent front view of a partition plate at the back of the freezer compartment of the refrigerator of the present invention. FIG. 9 is an enlarged vertical sectional side view of a lower part of a cooler of the refrigerator of the present invention. FIG. 10 is another enlarged vertical sectional side view of the lower part of the cooler of the refrigerator of the present invention. FIG. 11 is a front view of a refrigerator of the refrigerator of the present invention. FIG. 12 is a plan view of a refrigerator of the refrigerator of the present invention. FIG. 13 is a side view of a refrigerator of the refrigerator of the present invention. FIG. 14 is an exploded perspective view of an upper partition wall of the refrigerator of the present invention. FIG. 15 is a plan sectional view of an upper partition wall of the refrigerator of the present invention. FIG. 16 is a longitudinal sectional side view of a pre-partitioning member of the refrigerator of the present invention. FIG. 17 is an exploded perspective view of a water supply tank for an automatic ice maker of the refrigerator of the present invention. FIG. 18 is a vertical sectional side view of a water supply tank for an automatic ice maker of the refrigerator of the present invention. FIG. 19 is a vertical sectional front view of a water supply tank for an automatic ice maker of the refrigerator of the present invention. [Description of Signs] 1 Refrigerator 6 Insulated box 7 Middle partition 8 Upper partition 9 Lower partition 10 Ice hot room 11 Cold room 11A Cold room outlet 12 Vegetable room 13 Freezer room 13A Freezer room outlets 13B, 13C Freezer room Suction port 24 Cooling chamber 26 Coolers 26A, 26B, 26C Low fin density area 27 Fin 28 Refrigerant pipe 48 Ice greenhouse duct 63 Return duct 77, 78 Cooling room suction duct 79, 81 Cooling room front suction port 83 Communication passage 87 Vegetable Room duct

──────────────────────────────────────────────────続 き Continuing on the front page (72) Motoyuki Murasha 2-5-5 Keihanhondori, Moriguchi-shi, Osaka Sanyo Electric Co., Ltd. (72) Inventor Hiroshi Kibe 2-chome Keihanhondori, Moriguchi-shi, Osaka No. 5-5 Sanyo Electric Co., Ltd. (72) Inventor Kiyoshi Katagai 2-chome, Moriguchi-shi, Osaka 2-chome No. 5-5 Sanyo Electric Co., Ltd. (72) Inventor Osamu Mori 2-chome, Keihanhondori, Moriguchi-shi, Osaka No. 5-5 Inside Sanyo Electric Co., Ltd. (56) References JP-A-8-178509 (JP, A) JP-A-7-110182 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB Name) F25D 17/08 304 F25D 17/08 307

Claims (1)

(57) [Claims 1] A heat insulation box body opened to the front is partitioned by a partition wall, so that a freezing room, an ice green room above and below the freezing room and a vegetable room, and a refrigerator above the ice green room are refrigerated. and forming a chamber, said cooling chamber formed in the deeper of the freezing chamber and condenser was placed the blower, the refrigerator was cooled cold air comprising supplying to each chamber by the blower by the cooler, the Cold air circulating in the refrigerator compartment and the ice compartment is fed to the vegetable compartment.
In addition to providing a vegetable compartment duct to supply, the refrigerator compartment and the front
Cold air is supplied to the ice greenhouse in the partition wall that partitions the ice greenhouse.
The ice greenhouse duct to be supplied and the cold air circulating in the refrigerator compartment
Refrigerator suction ducts are installed side by side.
To the vegetable compartment duct, and
To connect the ice greenhouse duct and the refrigerator compartment suction duct
Thus, a part of the cold air supplied to the ice greenhouse is directly supplied to the vegetable compartment duct .