JP2024056341A - refrigerator - Google Patents

Abstract

The present disclosure provides a refrigerator capable of achieving uniform temperature inside the refrigerator compartment. [Solution] A refrigerator 1 is provided with a refrigeration cooler 54 (cooler) at the back of a refrigerator compartment 11, a blower fan 70 having a rotating fan 71 housed in a fan casing 72, and an air duct structure 33 connected to a fan outlet 74 of the fan casing 72 to guide cold air to the refrigerator compartment 11, the air duct structure 33 is provided with a main air duct 34 which communicates with a refrigeration outlet 37 (upper outlet) of the refrigerator compartment 11 to guide cold air to the upper part of the refrigerator compartment 11, and a plurality of secondary air ducts 35 which branch off to the left and right from the main air duct 34 and communicate with side outlets 38 of the refrigerator compartment 11 to guide cold air to the left and right of the refrigerator compartment 11, a rib member 41 is arranged on the inlet side of the main air duct 34 so as to narrow an air duct width 34A on the side where a larger amount of cold air passes through the fan outlet 74, and the rib member 41 is arranged at an angle so as to gradually widen the narrowed air duct width 34A toward an upper end 41B of the rib member 41. [Selected figure] Figure 3

Description

This disclosure relates to refrigerators.

Patent document 1 discloses a technology in which an air passage that guides cold air into the refrigerator compartment in a refrigerator is formed as a directional flow path using a blower fan, reducing the bias of the airflow caused by the rotation of the blower fan.

JP 2019-78493 A

This disclosure provides a refrigerator that can equalize the temperature inside the refrigerator compartment.

In the first aspect, a refrigerator is provided with a cooler at the rear of a refrigerator compartment, a fan casing having a rotating fan, and an air passage structure connected to the fan outlet of the fan casing to guide cold air into the refrigerator compartment, the air passage structure includes a main air passage that communicates with the upper outlet of the refrigerator compartment to guide cold air to the upper part of the refrigerator compartment, and a plurality of secondary air passages that branch off to the left and right from the main air passage and communicate with the side outlets of the refrigerator compartment to guide cold air to the left and right of the refrigerator compartment, and a rib member is disposed on the inlet side of the main air passage so as to narrow the air passage width on the side where the amount of cold air passing through the fan outlet is large, and the rib member is disposed at an angle so as to gradually widen the narrowed air passage width toward the upper end side of the rib member.

In the second aspect, a refrigerator is provided with a cooler, a blower fan, and an air passage structure connected to the fan outlet of the blower fan on the rear side of the refrigerator compartment to guide cold air into the refrigerator compartment, the air passage structure is attached by overlapping a partition plate and a molded insulation material, and the molded insulation material is in contact with the inner surface of the inner box of the refrigerator compartment, and between the partition plate and the molded insulation material, a main air passage that communicates with the upper air outlet of the refrigerator compartment to guide cold air to the upper part of the refrigerator compartment, and multiple sub-air passages that branch off to the left and right from the main air passage and communicate with the side air outlets of the refrigerator compartment to guide cold air to the left and right of the refrigerator compartment, and the partition plate protrudes directly above the fan outlet and has a curved portion at its lower end to suppress air passage resistance of the cold air.

This disclosure makes it possible to equalize the temperature inside the refrigerator compartment.

FIG. 1 is a vertical cross-sectional view of a refrigerator according to a first embodiment. FIG. 1 is an exploded perspective view of a duct portion according to a first embodiment; FIG. 1 is a front view of a cooling chamber portion according to the first embodiment; 1 is a rear view of a blower fan portion according to the first embodiment; A diagram showing the results of a simulation showing the wind speed of air flowing inside the fan casing of a blower fan. AA cross-sectional view of FIG.

(Knowledge and other information that forms the basis of this disclosure)
At the time when the inventors came up with the present disclosure, there was a technology in a refrigerator in which an air passage for guiding cold air to a refrigerator compartment is formed as a directional flow path by a blower fan, thereby reducing bias in airflow caused by the rotation of the blower fan. The inventors discovered a problem in such a refrigerator in which cold air is guided to the refrigerator compartment only from the upper part, making it difficult to achieve a uniform temperature in the refrigerator compartment. In order to solve this problem, the inventors came up with the subject of the present disclosure.
In view of the above, the present disclosure provides a refrigerator capable of achieving uniform temperature in the refrigerator compartment.

Hereinafter, the embodiments will be described in detail with reference to the drawings. However, more detailed explanation than necessary may be omitted. For example, detailed explanation of already well-known matters or duplicate explanation of substantially the same configuration may be omitted. This is to avoid the following explanation becoming more redundant than necessary and to facilitate understanding by those skilled in the art.
It should be noted that the accompanying drawings and the following description are provided to enable those skilled in the art to fully understand the present disclosure, and are not intended to limit the subject matter described in the claims.

(Embodiment 1)
Hereinafter, the first embodiment will be described with reference to FIGS.
[1-1. Configuration]
[1-1-1. Configuration of refrigerator]
Fig. 1 is a vertical cross-sectional view of a refrigerator in accordance with embodiment 1. Fig. 2 is an exploded perspective view of a duct portion in accordance with embodiment 1. Fig. 3 is a front view of a cooling chamber portion in accordance with embodiment 1.
In the description of this specification, references to the front, back, left and right of refrigerator 1 are based on Fig. 1 and Fig. 3. That is, the left and right of Fig. 1 will be described as corresponding to the front and back of refrigerator 1. Also, the left and right of Fig. 3 will be described as corresponding to the left and right of refrigerator 1. Note that the front side of refrigerator 1 may be referred to as the "front". Also, the rear side of refrigerator 1 may be referred to as the "rear".

As shown in Fig. 1, the refrigerator 1 includes a box-shaped housing 10 with an open front. A compressor 5 is mounted on the rear of the upper surface of the housing 10. The housing 10 includes an inner box 2 and an outer box 3, and a urethane insulation material 4 is filled between the inner box 2 and the outer box 3.
A refrigerator compartment 11 with a temperature of about 2° C. to 4° C. is formed in the upper part of the housing 10 as a storage compartment, and a freezer compartment 12 with a temperature of about -18° C. is formed in the lower part of the housing 10. A switchable compartment 13 is formed between the refrigerator compartment 11 and the freezer compartment 12. The switchable compartment 13 can be used as a low-temperature compartment with a temperature of about -5° C. to about 1° C. or as the freezer compartment 12 by operating a selector switch (not shown).

In the refrigerator 1, a revolving door 14 is provided at the opening on the front side of the refrigeration chamber 11 so as to be able to be opened and closed freely.
Below the refrigerator compartment 11, there are provided a vegetable compartment 15 as a storage compartment located on the upper level, and a micro-freezing compartment 16 as a storage compartment located on the lower level.
The vegetable compartment 15 is provided with a vegetable compartment pull-out case 17, and the micro-freezing compartment 16 is provided with a micro-freezing compartment pull-out case 18.

A freezer compartment drawer door 19 is provided at the opening on the front side of the freezer compartment 12 so as to be freely opened and closed, and a freezer compartment drawer case 20 having multiple stages for storing food therein is provided.
A switching room drawer door 21 is provided at the opening on the front side of the switching room 13 so as to be freely opened and closed, and a switching room drawer case 22 is provided which is linked to the opening and closing of the switching room drawer door 21.

As shown in FIG. 1, a refrigeration cooling compartment 30 is provided on the rear side of the refrigeration compartment 11 of the refrigerator 1.
The refrigerator compartment 11 and the refrigerator cooling compartment 30 are separated by a first partition plate 31, and a first molded insulation material 32 having approximately the same outline as the first partition plate 31 is provided on the back side of the first partition plate 31.

As shown in FIG. 2 , a first partition plate 31 and a first molded insulating material 32 are overlapped to form an air passage structure 33 .
The air passage structure 33 is attached in contact with the rear surface of the inner box 2 (see FIG. 1). The first partition plate 31 is a flat metal plate material with three sides bent to form a flange 55. The lower side of the first partition plate 31 is curved downwardly to form a curved portion 56, and both ends of the curved portion 56 are covered with cover members 57. The surface of the first molded insulating material 32 facing the first partition plate 31 is formed with a main groove 58 extending vertically and a sub-groove 59 connected to the main groove 58 and extending horizontally.

The first molded insulation material 32 fits between the flanges 55 of the first partition plate 31, and the first partition plate 31 and the first molded insulation material 32 are overlapped with surface contact. A curved portion 32A that is convex downward is formed on the lower edge of the first molded insulation material 32, and the curved portion 56 of the first partition plate 31 overlaps the upper surface of the curved portion 32A.

3, the air passage structure 33 includes a main air passage 34 extending in the up-down direction at approximately the center in the left-right direction, and two sub-air passages 35 each extending obliquely upward in the left-right direction and communicating with the main air passage 34. The main air passage 34 is formed by the main groove 58, and the sub-air passages 35 are formed by the sub groove 59.
At the lower end of the main air passage 34, a refrigeration inlet 36 communicating with a fan outlet 74 of a blower fan 70 (described later) is formed, and the refrigeration inlet 36 is located approximately in the center in the left-right direction of the refrigerator 1. At the upper end of the main air passage 34, a refrigeration outlet 37 communicating with the upper part of the refrigerator compartment 11 is formed. The refrigeration inlet 36 is formed in the curved portion 32A at the lower edge of the first molded insulation material 32, and the refrigeration outlet 37 is formed in the upper flange 55 of the first partition plate 31.

The sub-air passages 35 are tapered from left to right, and at the tip of each sub-air passage 35, a side air outlet 38 is formed which communicates with the side of the refrigerator compartment 11. The side air outlets 38 are formed in the flanges 55 on both sides of the first partition plate 31.
Front air outlets 39 that are arranged at a predetermined interval in the vertical direction and communicate with the refrigerator compartment 11 are formed in the middle of the main air passage 34 .
The front air outlets 39 are formed at a predetermined interval in the up-down direction on the plate surface of the first partition plate 31. The front air outlets 39 include an upper front air outlet 39U and a lower front air outlet 39D. When these are referred to collectively without distinction, they are referred to as the front air outlets 39. A straightening block 40 is provided near the upper part of the front air outlets 39. The straightening block 40 includes an upper straightening block 40U and a lower straightening block 40D. When these are referred to collectively without distinction, they are referred to as the straightening block 40.

The flow straightening block 40 creates airflow resistance in the main air passage 34. The lower surface of the flow straightening block 40D located below is formed in a flat shape, so that the cool air that collides with the flow straightening block 40D easily flows to the lower front air outlet 39D.
The underside of the straightening block 40U located at the top is inclined upward to the left and right, so that the cold air that collides with the inclined surface of the straightening block 40U easily flows along this inclined surface to the upper front air outlet 39U and the refrigeration air outlet 37.

A second partition plate 50 and a third partition plate 51 are provided between the vegetable compartment 15 and the micro-freezing compartment 16 and the refrigeration cooling compartment 30.
A second shaped insulating material 52 is provided between the second partition plate 50 and the third partition plate 51. The second partition plate 50, the third partition plate 51 and the second shaped insulating material 52 constitute the partition portion of the present disclosure.

A refrigeration inlet 53 communicating with the slight freezing chamber 16 is formed at the lower ends of the second partition plate 50, the second molded insulation material 52 and the third partition plate 51.
A refrigeration cooler 54 is provided below the rear surface of the second partition plate 50. A blower fan 70 is provided above the second partition plate 50.

A freezing cooling compartment 60 is provided on the rear side of the freezing compartment 12 and the switching compartment 13 of the refrigerator 1.
The freezing chamber 12 and the freezing cooling chamber 60 are separated by a fourth partition plate 61. The fourth partition plate 61 is formed with a freezing suction port 62 that communicates with the freezing chamber 12 and takes in the cold air from the freezing chamber 12 into the freezing cooling chamber 60.
The fourth partition plate 61 is formed with a freezer air outlet 63 communicating with the freezer compartment 12 and a switching compartment air outlet 64 communicating with the switching compartment 13 .

2, a first slit 155 is formed in the lower part of the flange 55 on both sides of the first partition plate 31, and a second slit 157 is formed in the lower left end of the plate surface of the first partition plate 31 in the figure. Also, first notches 159, 161 are formed in both sides of the lower part of the first molded insulation material 32, and a second notch 163 is formed in the lower left end in the figure.
The cold air in the refrigerator compartment 11 is sucked into the fan inlet 73 of the blower fan 70 shown in Fig. 4, which will be described later. That is, when the blower fan 70 rotates, the cold air in the refrigerator compartment 11 passes through the slits 155 and 157 of the first partition plate 31, reaches the notches 159, 161 and 163 of the first molded insulation material 32, flows downward through a return air duct (not shown) on the back side of the blower fan 70, and flows around to below the refrigerator cooler 54, where it is cooled again, and is sucked into the fan inlet 73 of the blower fan 70.

The freezing cooling chamber 60 accommodates a freezing cooler 65 .
The freezing cooler 65 is, for example, a fin tube type cooler. The fin tube type cooler is, for example, a cooler composed of a circular pipe and flat fins. A freezing fan 66 is disposed above the freezing cooler 65 to send the cold air cooled by the freezing cooler 65 into the freezing chamber 12.

For example, an axial fan is used as the refrigeration fan 66. The axial fan is disposed at an incline so that the blowing side faces upward so that the cold air cooled by the refrigeration cooler 65 can be efficiently blown out into the freezing chamber 12.
The refrigeration fan 66 may be, for example, a centrifugal fan.
A heater 67 such as a glass tube heater is disposed below the cryocooler 65 in order to remove frost adhering to the cryocooler 65 .
A freezer dew tray 68 is disposed below the freezer cooler 65 .

Next, the configuration of the blower fan portion will be described.
FIG. 4 is a rear view of the blower fan portion in the first embodiment, in which the internal configuration is seen through to make the inside of the fan casing 72 easier to understand.

4, the blower fan 70 includes a rotary fan 71 and a fan casing 72 that covers the rotary fan 71. The blower fan 70 is configured to suck air in from the direction of the rotation axis of the rotary fan 71 and blow the air in the radial direction of the rotary fan 71.
Fan casing 72 is formed in a spiral shape that gradually widens from the center of rotation of blower fan 70. In this embodiment, fan casing 72 is formed in a shape such that an upper portion of rotating fan 71 of blower fan 70 is closest to rotating fan 71, and the shape gradually widens to extend to approximately the center of refrigerator 1 in the left-right direction.

A fan suction port 73 that draws in air by the rotation of the rotary fan 71 is formed on the surface of the fan casing 72. A fan outlet 74 that communicates with the refrigeration inlet 36 of the main air passage 34 is formed on the upper part of the fan casing 72.
Fan outlet 74 of fan casing 72 is located at approximately the center in the left-right direction of refrigerator 1. Therefore, the center of rotation of rotating fan 71 is shifted to one side (to the left when viewed from the front side) with respect to the center in the left-right direction of refrigerator 1.

The rotary fan 71 of the blower fan 70 is attached to the rear side of the second partition plate 50. The portion of the second partition plate 50 where the rotary fan 71 is attached is provided with a fan attachment portion (not shown) having an opening.
A casing mounting recess having substantially the same shape as the outer shape of the fan casing 72 is formed around the fan mounting portion.

The lower part of the fan casing 72 is formed as an inclined surface 77 that is inclined obliquely upward. A bent portion 78 is formed in the middle of the inclined surface 77 by recessing a part of the inclined surface 77 toward the inside of the fan casing 72.
An outwardly extending flange portion 79 is formed on the outer periphery of the fan casing 72 .

A plurality of engaging claws (not shown) are provided at predetermined positions on the outside of the casing mounting recess (not shown) of the second partition plate 50 to engage with the flange portion 79 of the fan casing 72 and secure the fan casing 72 to the second partition plate 50.
This makes it possible to easily fix the fan casing 72 to the second partition plate 50 by engaging the flange portion 79 with the engaging claw.

An outlet opening 90 is formed in the upper surface of the second partition plate 50. The outlet opening 90 is disposed so that the fan outlet 74 of the fan casing 72 is positioned therein.
A mild freezing chamber inlet 91 is formed on one side of the outlet opening 90 of the second partition plate 50. A mild freezing chamber duct (not shown) is formed in the second molded insulation material 52, which connects the mild freezing chamber inlet 91 and a mild freezing chamber outlet 92 that opens into the mild freezing chamber 16.
A vegetable chamber inlet 94 is formed on the other side of the outlet opening 90 of the second partition plate 50. A vegetable chamber duct (not shown) is formed in the second molded insulation material 52, which communicates the vegetable chamber inlet 94 with a vegetable chamber outlet 95 that opens into the vegetable chamber 15.
Between the blow-out opening 90 and the inlet 91 for the micro-freezing compartment and the inlet 94 for the vegetable compartment, there is provided a roughly triangular straightening member 97 that protrudes downward toward the windward side.

The blow-out opening 90 is provided with a damper 81. The damper 81 is located approximately in the center in the left-right direction, and is composed of a refrigeration damper 82 that adjusts the flow rate of cold air to the refrigeration inlet 36 of the air passage structure 33, a micro-freezing chamber damper 83 that adjusts the flow rate of cold air to the micro-freezing chamber duct (not shown), and a vegetable chamber damper 84 that adjusts the flow rate of cold air to the vegetable chamber duct (not shown).

Fig. 5 is a diagram showing the results of a simulation showing the wind speed of air flowing inside fan casing 72, and the internal configuration is shown in a see-through manner so that the inside of fan casing 72 can be easily seen. Fig. 5 is a diagram showing refrigerator 1 as seen from the back. Note that the direction of the arrow in the diagram indicates the direction of air flow, and the length of the arrow indicates the magnitude of the wind speed of the air. Rotating fan 71 is driven to rotate in the clockwise direction in the diagram.
As shown in Fig. 5, the fan outlet 74 is located approximately in the center of the refrigerator compartment 11 in the left-right direction, and the center of rotation of the rotary fan 71 is shifted to one side (to the right when viewed from the back of the refrigerator 1) with respect to the center of the refrigerator compartment 11 in the left-right direction. If the blower fan 70 is shifted to the side, the rotation of the rotary fan 71 generates an air flow mainly along the lower end of the fan casing 72. Therefore, there is a risk that the air flow will concentrate on the left side of the fan casing 72 in Fig. 5.

[1-2. Configuration of rib member]
In the first embodiment, a rectifying rib member 41 extending linearly in the vertical direction is provided at the lower portion of the main air passage 34 between the refrigeration inlet 36 and the lower front air outlet 39D. The rib member 41 is disposed between the two sub-air passages 35 located at the lower portion, i.e., at the branching position of the main air passage 34 and the sub-air passage 35.

The rib member 41 is formed integrally with the first molded insulation material 32 and is arranged to contact the first partition plate 31 and divide the main air passage 34. The rib member 41 is arranged on the inlet side of the main air passage 34 so that the lower end 41A narrows the air passage width 34A on the side where the amount of cool air passing through the fan outlet 74 is greater. The rib member 41 is arranged at an angle so that the narrowed air passage width 34A gradually widens toward the upper end 41B of the rib member 41. On the side of the upper end 41B of the rib member 41, the main air passage 34 has an approximately equal air passage width 34B on both the left and right sides.

According to the first embodiment, the air passage width 34A on the side where the amount of cold air passing through the fan outlet 74 is large is narrowed at the lower end 41A of the rib member 41, so the air passage resistance on the side where the amount of air is large increases, and on the side of the upper end 41B of the rib member 41, the air passage width 34B is approximately equal on the left and right, so the amount of cold air passing through the fan outlet 74 is approximately uniform across the entire width of the fan outlet 74.

According to this embodiment 1, the air volume at the entrance of the main air passage 34 is approximately equalized on the left and right of the rib member 41, the cold air flowing in from the refrigeration inlet 36 is discharged evenly from the side outlets 38 to the refrigerator chamber 11 via each sub-air passage 35, and the cold air that collides with the rectification block 40D is discharged evenly from the front outlets 39D to the refrigerator chamber 11. In addition, part of the cold air that collides with the rectification block 40U is discharged from the front outlets 39U to the refrigerator chamber 11, and the remaining cold air passes through the main air passage 34 and is blown out from the refrigeration outlet 37 at the top into the refrigerator chamber 11, thereby achieving uniform temperature inside the refrigerator chamber 11.

FIG. 6 is a cross-sectional view taken along line AA of FIG.
The air passage structure 33 is attached by overlapping the first partition plate 31 and the first molded insulation material 32 and bringing the molded insulation material 32 into contact with the inner surface of the inner box 2 of the refrigerator compartment 11.

The first partition plate 31 is recessed toward the rear side so as to approach the inner box 2, and therefore the first partition plate 31 is configured to protrude directly above the fan outlet 74. A curved portion 56 is formed at the lower end of the first partition plate 31 to reduce airflow resistance of the cool air.
Since the first partition plate 31 is configured to protrude directly above the fan air outlet 74, the capacity of the refrigerator compartment 11 can be increased accordingly.
Furthermore, even if the first partition plate 31 protrudes directly above the fan outlet 74, a curved portion 56 is formed at the lower end of the first partition plate 31, and therefore, the cool air flows along this curved portion 56, thereby reducing airflow resistance.
The first partition plate 31 corresponds to an example of a "partition plate".

The space between the inner box 2 and the outer box 3 is filled with urethane insulation material 4, and a first molded insulation material 32 is fixed to the surface of the inner box 2 together with a first partition plate 31 by a fixing member (not shown). The first molded insulation material 32 is an example of a "molded insulation material."

[1-3. Operation, etc.]
Next, the operation of the refrigerator 1 in the first embodiment will be described.
In this embodiment, the compressor 5 is driven to send the refrigerant to the refrigerant circuit, and the refrigerant is selectively circulated to the refrigeration cooler 54 or the freezing cooler 65. The cooling device 65 is cooled.
Then, by driving the blower fan 70, the air inside the refrigerator compartment 11 is sucked into the refrigerator cooling compartment 30 through the refrigerator suction port 53. The air sucked into the refrigerator cooling compartment 30 is then cooled by the refrigerator cooler 54. The refrigerant flows from the bottom to the top, is cooled by heat exchange with the refrigeration cooler 54 in which the refrigerant flows, and is sucked into the fan casing 72 through the fan suction port 73.

The air drawn into the fan casing 72 is blown out in the circumferential direction by the rotary fan 71 , guided along the underside of the fan casing 72 , and blown out from the fan outlet 74 towards the main air passage 34 .
The air blown into the main air passage 34 passes through the main air passage 34 and the sub-air passage 35 and is then blown out from the refrigeration outlet 37, the side outlet 38, and the front outlet into the refrigerator compartment 11, thereby cooling the refrigerator compartment 11.

On the other hand, a portion of the air in the fan casing 72 is blown out from the slight freezing chamber opening through a slight freezing chamber duct (not shown) and into the slight freezing chamber 16 through the slight freezing chamber outlet 92.
Similarly, a portion of the air from the fan casing 72 is blown out from the vegetable compartment opening through a vegetable compartment duct (not shown) and into the vegetable compartment 15 through the vegetable compartment outlet 95 .
The flow rate of air sent to the main air passage 34, the opening for the slight freezing compartment, and the opening for the vegetable compartment is adjusted by the opening amount of the refrigeration damper 82, the damper 83 for the slight freezing compartment, and the damper 84 for the vegetable compartment.

In addition, by driving the freezing fan 66, the air inside the freezing chamber 12 is sucked from the suction port of the freezing chamber 12 into the freezing cooling chamber 60. The air sucked into the freezing cooling chamber 60 flows from the bottom to the top through the freezing cooler 65, and is cooled by heat exchange with the freezing cooler 65 through which the refrigerant flows.
The air cooled by heat exchange with the refrigeration cooler 65 is blown out into the freezing chamber 12 through the refrigeration outlet 63, and also blown out into the switching chamber 13 through the switching chamber outlet 64, thereby cooling the freezing chamber 12 and the switching chamber 13.

In this embodiment 1, a rib member 41 is formed in the main air passage 34, so that the air sent from the fan outlet 74 to the refrigeration inlet 36 is equally separated to the left and right by the rib member 41 and flows through the main air passage 34.

In addition, the cold air blown out from the fan outlet 74 collides with the lower end of the first partition plate 31 before reaching the air passage structure 33, and changes the air direction to the rearward direction as shown in Fig. 6. At this time, since the lower end of the first partition plate 31 has the curved portion 56, resistance to the cold air is reduced.
Furthermore, since the first molded insulating material is provided on the inner surface of the inner box 2, the detouring of cold air can be relatively suppressed.

[1-4. Effects, etc.]
As described above, in the present embodiment, in the refrigerator 1 provided with the refrigeration cooler 54 (cooler) at the rear side of the refrigeration chamber 11, the blower fan 70 having the rotary fan 71 housed in the fan casing 72, and the air passage structure 33 connected to the fan outlet 74 of the fan casing 72 to guide cool air to the refrigeration chamber 11, the air passage structure 33 communicates with the refrigeration outlet 37 (upper outlet) of the refrigeration chamber 11 to guide the cool air to the upper part of the refrigeration chamber 11. and a plurality of sub-air ducts 35 which branch off to the left and right from the main air duct 34, communicate with side air outlets 38 of the refrigerator compartment 11, and guide cold air to the left and right of the refrigerator compartment 11. A rib member 41 is disposed on the inlet side of the main air duct 34 so as to narrow an air duct width 34A on the side where a larger amount of cold air passes through the fan air outlet 74, and the rib member 41 is disposed at an angle so as to gradually widen the narrowed air duct width 34A toward an upper end 41B of the rib member 41.
As a result, the amount of air flowing through the main air passage 34 can be made uniform between the left and right sides by the rib member 41. Therefore, the temperature inside the refrigerator compartment 11 can be made uniform.

In addition, in this embodiment, the fan outlet 74 is located approximately in the center of the refrigerator compartment 11 in the left-right direction, and the center of rotation of the rotating fan 71 may be shifted to one side relative to the center of the refrigerator compartment 11 in the left-right direction.
As a result, the amount of air flowing through the main air passage can be made uniform between the left and right sides by the rib member 41. This makes it possible to equalize the temperature inside the refrigerator compartment.

In the present embodiment, the air passage structure 33 may include a plurality of front air outlets 39 that communicate with the main air passage 34 and guide cool air to the center of the refrigerator compartment 11 .
This makes it possible to make the amount of cold air flowing into the refrigerator compartment 11 uniform in the vertical direction. Therefore, the temperature inside the refrigerator compartment 11 can be made uniform.

In the present embodiment, air-path structure 33 may include a rectifying block 40 that protrudes into main air path 34 above front air outlet 39 and serves as air-path resistance.
This makes it easier for cool air to be guided to the front air outlet 39, and makes it possible to make the amount of cool air flowing into the refrigerator compartment 11 uniform in the vertical direction. Therefore, the temperature inside the refrigerator compartment 11 can be made uniform.

In the present embodiment, the rib member 41 may be disposed at a branch position of the main air passage 34 and the sub-air passage 35 .
This allows a uniform amount of cool air to be guided to the sub-air ducts 35 branching to the left and right. This allows the temperature inside the refrigerator compartment 11 to be uniform.

In the present embodiment, the sub-air passage 35 may be formed so that the air passage width gradually narrows toward the side air outlet 38 .
This makes it possible to prevent the flow of cold air from concentrating in the sub-air duct 35. Therefore, the temperature inside the refrigerator compartment 11 can be made uniform.

In the present embodiment, in refrigerator 1 including refrigeration cooler 54 (cooler) at the rear side of refrigeration compartment 11, blower fan 70 having rotating fan 71 housed in fan casing 72, and air passage structure 33 connected to fan outlet 74 of fan casing 72 to guide cool air to refrigeration compartment 11, air passage structure 33 includes first partition plate 31 (partition plate) and first molded insulating material 32 (molded insulating material) superimposed thereon to form first molded insulating material 32 into the inner box of refrigeration compartment 11. 2, and between the first partition plate 31 and the first molded insulation material 32, there is a main air duct 34 that communicates with a refrigeration outlet 37 (upper air outlet) of the refrigerator compartment 11 to guide cold air to the upper part of the refrigerator compartment 11, and a plurality of secondary air ducts 35 that branch off to the left and right from the main air duct 34 and communicate with side air outlets 38 of the refrigerator compartment 11 to guide cold air to the left and right of the refrigerator compartment 11. The first partition plate 31 protrudes directly above the fan air outlet 74, and has a curved portion 56 at its lower end that suppresses air duct resistance of the cold air.
This reduces the resistance to the cold air flowing from the fan casing 72 to the main air duct 34. Therefore, the temperature inside the refrigerator compartment 11 can be made uniform.

Other Embodiments
Note that the first embodiment has been described as an example of the technology disclosed in the present application. However, the technology in the present disclosure is not limited to this, and can be applied to embodiments in which modifications, substitutions, additions, omissions, and the like are made.

(Additional Note)
The above description of the embodiments discloses the following techniques.

(Technique 1)
a blower fan having a rotating fan housed in a fan casing; and an air passage structure connected to a fan outlet of the fan casing and directing cold air into the refrigerator compartment, the air passage structure comprising: a main air passage that communicates with an upper outlet of the refrigerator compartment and directs cold air to an upper portion of the refrigerator compartment; and a plurality of secondary air passages that branch off to the left and right from the main air passage and communicate with side outlets of the refrigerator compartment and direct cold air to the left and right of the refrigerator compartment, a rib member is disposed on the inlet side of the main air passage so as to narrow the air passage width on the side where a larger amount of cold air passes through the fan outlet, and the rib member is disposed at an angle so as to gradually widen the narrowed air passage width toward an upper end side of the rib member.
According to this configuration, the amount of air flowing through the main air passage can be made uniform between the left and right sides by the rib member, thereby making it possible to equalize the temperature inside the refrigerator compartment.

(Technique 2)
The refrigerator described in Technology 1, wherein the fan outlet is located in approximately the center of the refrigerator compartment in the left-right direction, and the center of rotation of the rotating fan is shifted to one side with respect to the center of the refrigerator compartment in the left-right direction.
According to this configuration, the amount of air flowing through the main air passage can be made uniform between the left and right sides by the rib member, thereby making it possible to equalize the temperature inside the refrigerator compartment.

(Technique 3)
The refrigerator according to claim 1, wherein the air passage structure includes a plurality of front air outlets that communicate with the main air passage and guide cool air to a center of the refrigerator compartment.
According to this configuration, the amount of cold air flowing into the refrigerator compartment can be made uniform in the vertical direction, thereby making it possible to equalize the temperature inside the refrigerator compartment.

(Technique 4)
The refrigerator according to Technology 1 or 2, wherein the air passage structure includes a straightening block that protrudes into the main air passage above the front air outlet and serves as air passage resistance.
According to this configuration, the cool air can be easily guided to the front air outlet, and the amount of cool air flowing into the refrigerator compartment can be made uniform in the vertical direction, thereby making it possible to equalize the temperature inside the refrigerator compartment.

(Technique 5)
The refrigerator according to any one of Techniques 1 to 3, wherein the rib member is arranged at a branching position between the main air passage and the sub-air passage.
According to this configuration, a uniform amount of cool air can be guided to the sub-air ducts branching to the left and right, thereby making it possible to equalize the temperature inside the refrigerator compartment.

(Technique 6)
The refrigerator according to any one of Techniques 1 to 4, wherein the sub-air passage is formed so that the air passage width gradually narrows toward the side air outlet.
According to this configuration, it is possible to prevent the flow of cold air from concentrating in the sub-air duct, thereby making it possible to equalize the temperature inside the refrigerator compartment.

(Technique 7)
A refrigerator having a cooler and a blower fan on the rear side of a refrigerator compartment, and an air passage structure connected to the fan outlet of the blower fan to guide cold air into the refrigerator compartment, wherein the air passage structure is attached by overlapping a partition plate and a molded insulation material and contacting the molded insulation material with the inner surface of the inner box of the refrigerator compartment, and between the partition plate and the molded insulation material, there is a main air passage that communicates with the upper outlet of the refrigerator compartment to guide cold air to the upper part of the refrigerator compartment, and a plurality of secondary air passages that branch off to the left and right from the main air passage and communicate with the side outlets of the refrigerator compartment to guide cold air to the left and right of the refrigerator compartment, and the partition plate protrudes directly above the fan outlet and has a curved portion at its lower end to suppress air passage resistance of the cold air.
This configuration reduces resistance to cold air, making it possible to equalize the temperature inside the refrigerator compartment.

As described above, the refrigerator according to the present disclosure can be suitably used in refrigerators that can equalize the volume of air sucked in and the volume of air blown out by the blower fan across the width of the refrigerator.

REFRIGERATION LIST 1 Refrigerator 2 Inner box 3 Outer box 4 Urethane insulation material 5 Compressor 10 Housing 11 Refrigerating compartment 12 Freezing compartment 13 Switching compartment 14 Door 15 Vegetable compartment 16 Micro-freezing compartment 17 Drawer case for vegetable compartment 18 Drawer case for micro-freezing compartment 19 Drawer-type door for freezer compartment 20 Drawer case for freezer compartment 21 Drawer-type door for switching compartment 22 Drawer case for switching compartment 30 Refrigerating compartment 31 First partition plate (partition plate)
32 First molded insulation material (molded insulation material)
32A Curved portion 33 Air passage structure 34 Main air passage 34A, 34B Air passage width 35 Sub-air passage 36 Refrigeration inlet 37 Refrigeration outlet (upper outlet)
38 Side air outlet 39, 39D, 39U Front air outlet 40, 40D, 40U Flow straightening block 41 Rib member 41A Lower end 41B Upper end 50 Second partition plate 51 Third partition plate 52 Second molded insulation material 53 Refrigeration suction port 54 Refrigeration cooler 55 Flange 56 Curved portion 57 Cover member 58 Main groove 59 Sub-groove 60 Freezing cooling chamber 61 Fourth partition plate 62 Freezing suction port 63 Freezing air outlet 64 Room air outlet 65 Freezing cooler 66 Freezing fan 67 Heater 68 Freezing dew tray 70 Blower fan 71 Rotating fan 72 Fan casing 73 Fan suction port 74 Fan air outlet 77 Inclined surface 78 Inflection portion 79 Flange portion 81 Damper 82 Refrigeration damper 83 Freezing chamber damper 84 Vegetable chamber damper 90 Air outlet 91 Freezing chamber inlet 92 Freezing chamber outlet 94 Vegetable chamber inlet 95 Vegetable chamber outlet 97 Flow straightening member 155 First slit 157 Second slit 159 First notch 161 First notch 163 Second notch

Claims (7)

A refrigerator including a cooler at a rear surface of a refrigerator compartment, a blower fan having a rotary fan housed in a fan casing, and an air passage structure connected to a fan outlet of the fan casing to guide cool air into the refrigerator compartment,
The air passage structure includes:
A main air duct that communicates with the upper air outlet of the refrigerator compartment and guides cool air to an upper portion of the refrigerator compartment, and a plurality of sub-air ducts that branch off to the left and right from the main air duct and communicate with the side air outlets of the refrigerator compartment and guide cool air to the left and right of the refrigerator compartment,
a rib member is disposed on an inlet side of the main air passage so as to narrow an air passage width on a side where a larger amount of the cool air passing through the fan outlet is passed;
The rib member is disposed at an angle so as to gradually widen the narrowed air passage width toward an upper end side of the rib member.
refrigerator. The refrigerator according to claim 1, wherein the fan outlet is located in approximately the center of the refrigerator compartment in the left-right direction, and the center of rotation of the rotating fan is shifted to one side with respect to the center of the refrigerator compartment in the left-right direction. The air passage structure includes:
The refrigerator according to claim 1 , further comprising a plurality of front air outlets communicating with the main air passage and directing cool air to a center of the refrigerator compartment. The air passage structure includes:
The refrigerator according to claim 3 , further comprising a straightening block protruding into the main air passage above the front air outlet to provide air passage resistance. The rib member is disposed at a branching position between the main air passage and the sub-air passage.
2. The refrigerator according to claim 1. The auxiliary air passage is formed so that the width of the air passage gradually narrows toward the side air outlet.
2. The refrigerator according to claim 1. A refrigerator including a cooler, a blower fan, and an air passage structure connected to a fan outlet of the blower fan on the rear side of a refrigerator compartment to guide cool air into the refrigerator compartment,
The air passage structure includes:
The partition plate and the molded insulation material are overlapped, and the molded insulation material is attached in contact with the inner surface of the inner box of the refrigerator compartment,
Between the partition plate and the molded heat insulating material, a main air duct that communicates with the upper air outlet of the refrigerator compartment and guides cold air to the upper part of the refrigerator compartment, and a plurality of sub-air ducts that branch off to the left and right from the main air duct and communicate with the side air outlets of the refrigerator compartment and guide cold air to the left and right of the refrigerator compartment,
The partition plate extends directly above the fan outlet and has a curved portion at its lower end for reducing airflow resistance of the cool air.
refrigerator.

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