KR20210072667A - refrigerator - Google Patents

Abstract

According to the present invention, a grill pan assembly for a refrigerator proposes that portions of a first cold air guide passage and a second cold air guide passage formed in a grill pan are formed to be connected, thereby additionally supplying a portion of cold air flowing along the second cold air guide passage to the first cold air guide passage.

Description

refrigerator

The present invention relates to a refrigerator having a refrigerating compartment and a freezing compartment each providing a storage space, and an ice making compartment in the refrigerating compartment door.

BACKGROUND ART In general, a refrigerator is a home appliance that is provided to store various foods for a long time with cold air generated by using a circulation of a refrigerant according to a freezing cycle.

In such a refrigerator, one or a plurality of storage compartments for freezing and storing storage objects are provided while being partitioned from each other. In this case, the storage chamber may be a storage chamber that is opened and closed by a rotary door, or may be a storage chamber that can be taken out or stored in a drawer type.

In particular, the storage compartment may include a freezer compartment for freezing storage of a storage object and a refrigerating compartment for refrigeration storage of a storage object, and may include two or more freezing compartments or two or more refrigerating compartments.

On the other hand, a grill pan assembly is provided on the rear wall side of each storage compartment to separate a portion in which the stored material is stored and a portion in which the fan module is installed in the storage compartment from each other.

Such a grill pan assembly is usually provided one by one for each storage compartment, and serves to circulate cold air in the corresponding storage compartment.

That is, each fan module is provided for each grill fan assembly, and the cooling air is supplied into the storage chamber by the air blowing power by the fan module or the cold air is circulated in the storage chamber. In this regard, as disclosed in Korean Patent Application Laid-Open No. 10-2006-0129664 and Registered Patent No. 10-0821711.

However, the above structure has a disadvantage in that it is not suitable for a structure for supplying cold air to two or more storage chambers with one evaporator. That is, since cold air is supplied to two or more storage chambers with a single blower fan, the cold air supply cannot be sufficiently performed and the overall flow path structure is inevitably complicated.

In consideration of this, a structure in which two blower fans are installed simultaneously in one grill fan assembly has been recently provided, which makes it possible to supply cold air to two or more storage rooms, respectively. In this regard, Patent Publication No. 10-2017-0133840 (Prior Art 1), Patent Publication No. 10-2018-0124451 (Prior Art 2), Patent Registration No. 10-1659622 (Prior Art 3), registration Patent No. 10-0918445 (Prior Art 4), Patent Publication No. 10-2006-0129664 (Prior Art 5), Patent Publication No. 10-2009-0101525 (Prior Art 6), etc. are as presented.

In particular, in the case of the prior art 3 to the prior art 6, an ice-making chamber is provided in the refrigerating chamber door, and one of the two blowing fans (ice-making fan) provided in the grill fan assembly supplies cool air that has passed through the evaporator to the ice-making chamber. As much as possible, in addition to the blowing box, another blowing fan (freezing fan) blows the cold air that has passed through the evaporator to be supplied to the freezing chamber, so that each control of the freezing chamber and the ice making chamber is possible.

Meanwhile, the freezing fan is configured to stop its operation when the temperature of the freezing chamber reaches a set temperature range. Accordingly, the refrigeration fan is controlled to repeat operation and stop at any time. On the other hand, the ice-making fan is controlled to continuously supply cold air to the ice-making chamber unless a special condition (eg, a condition in which the ice is full) is met in order to prevent defective ice-making.

In addition, the grill fan assembly provided with the ice making fan and the freezing fan is configured to receive cold air passing through the same single evaporator.

* In consideration of this, when cold air is to be supplied to the freezing chamber, only the freezing fan is rotated and the cold air passing through the evaporator is not only supplied to the freezing chamber, but the freezing fan and the ice making fan are rotated simultaneously in many cases.

That is, compared to the amount of cold air supplied to the freezing chamber when only the freezing fan is operated, the amount of cold air supplied to the freezing chamber when the freezing fan and the ice making fan are operated at the same time is relatively insufficient. In the case of a grill pan assembly provided at the same time, there is a problem that it takes a long time for the freezer compartment to reach the set temperature.

In addition, the above-described ice-making fan and the freezing fan have different uses, and in particular, the ice-making fan is a fan of a different type from the freezing fan because it is far from the ice-making chamber of the refrigerating chamber door.

However, since the ice making fan and the refrigeration fan are formed of different types of fans as described above, there is a difficulty in that the control or installation structure must be designed to suit the characteristics of each type of fan.

Patent Publication No. 10-2006-0129664 Registered Patent No. 10-0821711 Registered Patent No. 10-1659622 Laid-open Patent Publication No. 10-2017-0133840 Laid-Open Patent Publication No. 10-2018-0124451

The present invention has been devised to solve various problems according to the prior art described above, and an object of the present invention is to provide sufficient cold air supplied to the freezing chamber even if the freezing fan and the ice making fan are operated at the same time. An object of the present invention is to provide a refrigerator according to a new type in which the suction amount can always be secured as much as an appropriate suction amount.

Another object of the present invention is to provide a refrigerator according to a new type in which a refrigeration fan and an ice-making fan are applied in the same type so that the design for installation and control for operation can be made easily, and assembly and maintenance can be made easily. is to provide

Another object of the present invention is to provide a refrigerator according to a new type in which cooling air flows smoothly without interfering with each other when the freezing fan and the ice making fan operate.

The refrigerator of the present invention for achieving the above object proposes that a part of cold air flowing along the second cold air guide passage can be supplied to the first cold air guide passage, and through this, the cold air supplied to the freezing chamber is sufficiently supplied it was made to be

In addition, the refrigerator of the present invention suggests that the flow path rib is divided into the first flow rib and the second flow rib, and through this, the first cold air guide flow path and the second cold air guide flow path are divided between the first flow rib and the second flow rib. so that they can communicate with each other.

In addition, the refrigerator of the present invention suggests that the lower end of the first flow path rib and the upper end of the second flow path rib are positioned to be spaced apart from each other. It is designed so that it can flow by receiving guidance according to the shape of the end.

In addition, the refrigerator of the present invention suggests that the first flow path rib and the second flow path rib are formed so that the cold air blown from the ice making fan module flows into the first cold air guide flow path, and through this, a part of the cold air blown by the ice making fan module is reduced. It can also be supplied to the freezer compartment.

In addition, the refrigerator of the present invention proposes that a guide rib is formed at the lower end of the second flow path rib, and through this, the cold air flowing in the first cold air guide flow path is different from one end of the bottom surface of the first cold air guide flow path. It is designed to flow smoothly toward one end.

Further, in the refrigerator of the present invention, it is suggested that the lower end of the first flow path rib is formed to a length that is lower than the center of the freezing fan module or the center of the ice making fan module, and through this, the first flow rib and the second flow path are formed. The cold air in the second cold air guide passage can be smoothly supplied into the first cold air guide passage through the shared passage between the two passage ribs.

In addition, the refrigerator of the present invention suggests that the upper end of the second flow path rib is formed with a length that is higher than the center of the ice making fan module or the center of the freezing fan module, and through this, the first flow path rib and the second flow path rib are formed. The cold air in the second cold air guide passage can be smoothly supplied into the first cold air guide passage through the shared passage between the two passage ribs.

In addition, the refrigerator of the present invention suggests that the lower end of the first flow path rib is disposed to be positioned relatively close to the Zepping fan module compared to the upper end of the second flow path rib, and cold air blown by the operation of the ice making fan module through this This is so that the cold air can be smoothly supplied into the first guide flow passage through the common flow passage.

In addition, it is suggested that the refrigerator of the present invention includes a main cold air discharge unit located at the upper side in the first cold air guide passage, and through this, the cold air blown by the operation of the freezing fan module and the cold air blown by the operation of the ice-making fan module are provided. This is to ensure that there is enough supply to the freezer.

In addition, the refrigerator of the present invention suggests that the shared flow path is formed to face the main cold air discharge unit, so that the cold air blown by the operation of the ice-making fan module can be smoothly discharged to the main cold air discharge unit.

In addition, the refrigerator of the present invention suggests that the first flow path rib is formed in a round structure, so that the cold air can be discharged in a desired direction while minimizing the reverse flow.

In addition, the refrigerator of the present invention suggests that the second flow path rib is formed in a round structure, and through this, the cold air can be discharged in a desired direction while minimizing the backflow.

Further, it is suggested that the refrigerator of the present invention includes a first installation frame in which the refrigeration fan module is fastened and fixed to the grill pan with a plurality of fastening ribs, and through this, the refrigeration fan can be mounted in the correct position.

In addition, the refrigerator of the present invention suggests that the position of the fastening rib of the first installation frame is designed in consideration of the position between the two flow path ribs, through which cold air flowing by the operation of the refrigeration fan module is discharged between the two flow path ribs. was done to reduce

In addition, the refrigerator of the present invention suggests that a flow guide end is formed at one end of the upper surface of the first seating part on which the refrigeration fan module is mounted, through which the cold air flowing by the operation of the refrigeration fan module flows through the two flow paths. This is to reduce the discharge between the ribs.

In addition, the refrigerator of the present invention suggests that the positions of the two fastening ribs of the second installation frame are designed in consideration of the positions between the two flow path ribs, and through this, some of the cold air flowing by the operation of the ice-making fan module is transferred to the two flow paths. It is designed to be discharged smoothly between the ribs.

As described above, in the refrigerator of the present invention, as some of the cold air in the second cold air guide passage formed in the grill fan assembly is supplied to the first cold air guide passage through the shared passage, even if the freezing fan and the ice making fan are operated at the same time It has the effect that sufficient cold air can be supplied to the freezer compartment.

In addition, the refrigerator of the present invention provides the same type of refrigeration fan and ice-making fan, so that the design and operation of each fan can be easily controlled, and assembly and maintenance can be made easily. have

In addition, in the refrigerator of the present invention, when the freezing fan and the ice-making fan operate, the cold air, which passes through the shared flow path between the two flow path ribs formed in the grill fan assembly and is replenished into the first cold air guide flow path, flows through the first cold air guide flow path. It has the effect of being able to reduce the interference phenomenon of the cold air flow by preventing direct collision with the cold air.

In addition, in the refrigerator of the present invention, since the shared flow path between the first flow path rib and the second flow path rib formed in the grill fan assembly is configured to face the main cold air discharge unit, the cold air in the second cold air guide flow path can be supplied to the freezing chamber as well. have the effect of being

In addition, in the refrigerator of the present invention, the lower end of the first flow path rib and the upper end of the second flow path rib formed in the grill fan assembly are positioned to be spaced apart from each other, so that cold air passing between the two flow path ribs is provided in the two flow path ribs. It has the effect of being able to smoothly flow in a specific direction (the direction in which either end of the main cold air discharge part is located) according to the shape of the end.

In addition, in the refrigerator of the present invention, as the guide rib is formed at the lower end of the second flow path rib formed in the grill fan assembly, the cold air flowing to the bottom of the first cold air guide flow path can smoothly flow to the first auxiliary cold air discharge unit. have an effect

1 is a perspective view illustrating an external structure of a refrigerator according to an embodiment of the present invention;
2 is a perspective view schematically illustrating an internal structure of a refrigerator according to an embodiment of the present invention;
3 is a front cross-sectional view schematically illustrating an internal structure of a refrigerator according to an embodiment of the present invention;
4 is a side cross-sectional view schematically illustrating an internal structure of a refrigerator according to an embodiment of the present invention;
5 is an enlarged view of part “A” of FIG. 4
6 is an enlarged view illustrating the main part of a structure for supplying or recovering cold air to an ice-making chamber of a refrigerator according to an embodiment of the present invention;
7 is an exploded perspective view illustrating a grill pan assembly of a refrigerator according to an embodiment of the present invention;
8 is a front view illustrating a grill pan in a grill pan assembly of a refrigerator according to an embodiment of the present invention;
9 is a rear view illustrating a grill pan in a grill pan assembly of a refrigerator according to an embodiment of the present invention;
10 is a front view illustrating a shroud in a grill pan assembly of a refrigerator according to an embodiment of the present invention;
11 is a rear view illustrating a shroud in a grill pan assembly of a refrigerator according to an embodiment of the present invention;
12 is a perspective view illustrating a relationship for cold air transfer between a grill pan assembly of a refrigerator and an ice-making chamber according to an embodiment of the present invention;
13 is a front view illustrating a connection state between a grill pan assembly of a refrigerator and a cold air duct for a switching room and a return duct for a switching room according to an embodiment of the present invention;
14 is a rear view illustrating a connection state between the grill pan assembly of the refrigerator and the cold air duct for the switching room and the return duct for the switching room according to an embodiment of the present invention;
15 is a perspective view illustrating an open state of a switching damper provided in a grill pan assembly of a refrigerator according to an embodiment of the present invention;
16 is a perspective view illustrating a closed state of a switching damper provided in a grill pan assembly of a refrigerator according to an embodiment of the present invention;
17 is a cross-sectional view illustrating a main part of a switch damper provided in a grill pan assembly of a refrigerator in an open state when viewed from the front according to an embodiment of the present invention;
18 is a cross-sectional view illustrating a main part of a switch damper provided in a grill pan assembly of a refrigerator according to an embodiment of the present invention in a closed state when viewed from the front;
19 is a front view illustrating a fan module provided in a grill pan assembly of a refrigerator according to an embodiment of the present invention;
20 is a rear view illustrating a fan module provided in a grill pan assembly of a refrigerator according to an embodiment of the present invention;
21 is a state diagram showing the main part of the refrigerator in which the freezing fan module and the ice making fan module are installed, as viewed from the rear according to an embodiment of the present invention;
22 is a state diagram showing the main part of the shroud in which the freezing fan module and the ice making fan module of the refrigerator are installed, as viewed from the rear according to an embodiment of the present invention;
23 is a state diagram of a main part of a refrigerator as viewed from the rear of the shroud in a state in which the refrigeration fan module of the refrigerator is installed according to an embodiment of the present invention;
24 is a state diagram of a main part of a refrigerator viewed from the rear of the shroud in a state in which the ice-making fan module of the refrigerator is installed according to an embodiment of the present invention;
25 is an enlarged view of a main part shown to explain a flow path rib formed in a grill pan assembly of a refrigerator according to an embodiment of the present invention;
26 is a side cross-sectional view illustrating a flow of cold air during a freezing operation in a freezer compartment of a refrigerator according to an embodiment of the present invention;
27 is a state diagram illustrating the flow of cold air when the grill pan of the grill assembly is viewed from the rear during the freezing operation of the freezer compartment of the refrigerator according to an embodiment of the present invention;
28 is an enlarged view illustrating the flow of cool air by each flow path rib during a refrigeration operation of a freezing compartment of a refrigerator according to an embodiment of the present invention;
29 is a reference diagram illustrating a flow of cold air during a freezing operation in a freezing compartment of a refrigerator according to an embodiment of the present invention;
30 is an enlarged view illustrating the main part of a refrigerator according to an embodiment of the present invention to explain a flow of cool air by each flow path rib when a freezing operation and an ice-making operation are simultaneously performed;
31 is a reference diagram illustrating a flow of cold air when a freezing operation and an ice-making operation of the refrigerator are simultaneously performed according to an embodiment of the present invention;
32 is a side cross-sectional view illustrating a flow of cold air during a refrigeration operation in a switching room of a refrigerator according to an embodiment of the present invention;
33 is an enlarged view of part “B” of FIG. 32
34 is a state diagram illustrating a flow of cold air during a refrigeration operation in a switching room of a refrigerator according to an embodiment of the present invention;
35 is a state diagram illustrating a flow of cold air during an ice making operation in an ice making chamber of a refrigerator according to an embodiment of the present invention;
36 is an enlarged view illustrating main parts of a cooling air flow by each flow path rib during an ice-making operation in an ice-making chamber of a refrigerator according to an embodiment of the present invention;
37 is a side cross-sectional view illustrating a flow of cold air during an ice making operation in an ice making chamber of a refrigerator according to an embodiment of the present invention;
38 is a state diagram illustrating a flow of supply and recovery of cold air to and from the ice-making chamber during an ice-making operation for the ice-making chamber of the refrigerator according to an embodiment of the present invention;
39 is a perspective view illustrating an external structure of a refrigerator according to another embodiment of the present invention;
40 is a perspective view schematically illustrating an internal structure of a refrigerator according to another embodiment of the present invention;
41 is an exploded perspective view illustrating a grill pan assembly of a refrigerator according to another embodiment of the present invention;
42 is a front view illustrating a shroud in a grill pan assembly of a refrigerator according to an embodiment of the present invention;
43 is an enlarged view of part “C” of FIG. 42
44 is a front view illustrating a grill pan in a grill pan assembly of a refrigerator according to another embodiment of the present invention;
45 is a rear view illustrating a grill pan in a grill pan assembly of a refrigerator according to another embodiment of the present invention;
46 is a side cross-sectional view illustrating a flow of cold air during a freezing operation in the freezer compartment of a refrigerator according to another embodiment of the present invention;
47 is an enlarged view of the main part shown to explain the flow of cold air in the first cold air guide flow path during the freezing operation by the grill fan assembly for the refrigerator of FIG. 46;
48 is an enlarged view illustrating the main part of the refrigerator according to another embodiment of the present invention to explain the flow of cold air in the first cold air guide passage and the second cold air guide passage when the freezing operation and the ice making operation are simultaneously performed;
49 is a side cross-sectional view illustrating a flow of cold air during an ice making operation in an ice making chamber of a refrigerator according to another embodiment of the present invention;
50 is an enlarged view of the main part shown to explain the flow of cold air in the grill pan assembly of FIG. 49 in more detail;
52 is an enlarged view of main parts illustrating a flow of cold air in a second cold air guide flow path during an ice making operation of a refrigerator according to another embodiment of the present invention;

Hereinafter, a refrigerator according to preferred embodiments of the present invention will be described with reference to FIGS. 1 to 52 attached thereto.

1 is a perspective view illustrating an external structure of a refrigerator according to an embodiment of the present invention, and FIG. 2 is a perspective view schematically illustrating an internal structure of a refrigerator according to an embodiment of the present invention. , FIG. 3 is a front sectional view schematically illustrating the internal structure of a refrigerator according to an embodiment of the present invention, and FIG. 4 is schematically illustrating the internal structure of the refrigerator according to an embodiment of the present invention. It is a sectional side view shown, and FIG. 5 is an enlarged view of part “A” of FIG. 4 .

As shown in these drawings, the refrigerator according to an embodiment of the present invention includes a cabinet 10 having a refrigerating compartment 11, a freezing compartment 12 and a switching compartment 13, and a refrigerating compartment door ( 20), and the grill pan assemblies 1 and 2 are provided in the refrigerating compartment 11 and the freezing compartment 12 of the refrigerator, respectively.

In particular, the grill pan assembly for a refrigerator according to an embodiment of the present invention takes the grill pan assembly 1 provided in the freezing compartment 12 as an example, and has two fan modules 410 and 420 and one evaporator 32 ), it is characterized in that it is configured to selectively supply the heat-exchanged cold air to the freezing chamber 12, the switching chamber 13, and the ice-making chamber 21.

Here, the refrigerating compartment 11 and the freezing compartment 12 are spaces provided in front of each grill pan assembly 1 and 2 , and the refrigerating compartment 11 is a storage compartment provided to refrigerate stored items, and the freezing compartment 12 ) is a storage room provided for freezing storage.

The switching room 13 is a storage room provided to change its use according to the user's needs. At this time, since the change-over chamber 13 is configured to use the same evaporator 31 as the freezing chamber 12, the stored material stored in the change-over chamber 13 can be used not only for refrigeration storage but also for freezing storage. have.

At the same time, a first evaporator 31 is provided on the rear side of the refrigerating compartment 11 among the rear wall surfaces of the cabinet 10 , and a second evaporator 32 is provided on the rear side of the freezing compartment 12 among the rear wall surfaces of the cabinet 10 . ) is provided. The first evaporator 31 is an evaporator provided to supply cold air to the refrigerating compartment 11 , and the second evaporator 32 is directed to the freezing compartment 12 , the switching compartment 13 , and the ice making compartment 21 . It is an evaporator provided to supply cold air. This is as shown in FIGS. 4 and 5 .

In addition, the refrigerating compartment 11 is provided at the upper side of the cabinet 10 , the freezing compartment 12 is provided at the lower side of the cabinet 10 , and the switching compartment 13 is the refrigerating compartment 11 and the freezing compartment. (12) is provided in the middle layer in the cabinet (10). Each of these storage chambers (refrigeration chamber, freezing chamber, and switching chamber) 11 , 12 , 13 is formed while being partitioned from each other by a plurality of partition walls 14 dividing the inside of the cabinet 10 up and down.

In addition, the refrigerating compartment 11 is opened and closed by the refrigerating compartment door 20 , the freezing compartment 12 is opened and closed by the freezing compartment door 30 , and the switching compartment 13 is opened and closed by the switching compartment door 40 . .

At this time, the refrigerating compartment door 20 is formed of a rotary door rotating in a horizontal direction, and the freezing compartment door 30 and the switching compartment door 40 are formed of a drawer type door that slides back and forth.

In particular, the ice-making compartment 21 is installed inside the refrigerating compartment door 20 (the side located inside the refrigerating compartment when the refrigerating compartment door is closed). The ice making compartment 21 is a storage compartment in which an ice tray (not shown) for making ice is provided in the refrigerating compartment door 20 .

The ice-making chamber 21 is configured to receive cold air from the cold air duct 51 for the ice-making chamber through the guide duct 22 and then discharge the cold air to the recovery duct 52 for the ice-making chamber. This is as shown in the attached FIG. 6 .

In addition, a grill pan assembly 1 is provided in front of the second evaporator 32 in the cabinet 10 (freezing chamber), and another grill pan is provided in front (refrigeration chamber) of the first evaporator 31 in the cabinet 10 . An assembly 2 is provided. The grill pan assembly 1 provided in front of the second evaporator 32 and the grill pan assembly 2 provided in front of the first evaporator 31 may have the same structure or different structures.

At this time, the grill pan assembly 1 is not provided on the rear side of the switching chamber 13 among the rear wall surfaces of the cabinet 10 and cold air is selectively supplied from the grill pan assembly 1 on the front side of the second evaporator 32 . made to be supplied.

Although not shown, a compressor and a condenser constituting a refrigeration cycle are provided in the machine room 15 , thereby enabling heat exchange using the first evaporator 31 and the second evaporator 32 .

As shown in the attached FIG. 7 , the grill pan assembly 1 includes a grill pan 100 , a shroud 200 , a first cold air guide passage 310 and a second cold air guide passage 320 , It is configured to include a refrigeration fan module 410 and an ice-making fan module 420 , and flow ribs 510 and 520 .

In particular, in the grill pan assembly 1 of the refrigerator according to an embodiment of the present invention, a portion of cold air flowing along the second cold air guide passage 320 while the common passage G is formed in the passage ribs 510 and 520 . is to be supplied to the first cold air guide passage (310). Accordingly, the amount of cold air supplied to the freezing chamber through the first cold air guide passage 310 may be further increased.

The grill pan assembly 1 according to an embodiment of the present invention will be described in more detail for each configuration as follows.

First, the grill pan 100 will be described with reference to FIGS. 4 and 5 and FIGS. 7 to 11 .

The grill pan 100 is a portion forming the front wall of the grill pan assembly 1 and is located at the most front side of the grill pan assembly 1 . This is as shown in the accompanying Figures 4 and 5.

Cool air outlets 110 , 120 , and 130 are formed in the grill pan 100 (see attached FIGS. 7 to 9 ).

The cold air discharge units 110 , 120 , and 130 are holes formed for supplying cold air to the freezing chamber 12 , and are formed in a first cold air guide passage 310 to be described later.

The cold air discharge units 110 , 120 , and 130 include a main cold air discharge unit 110 formed on the central side of the grill pan 100 when viewed from the front (or rear side) of the grill pan 100 .

The main cold air discharge unit 110 is a portion in which the cold air forcedly blown by the rotation of the refrigerating fan module 410 is discharged to the space where the upper wall surface of the freezing chamber 12 is located.

The main cold air discharge unit 110 is formed to be positioned higher than the central portion of the freezing fan module 410 among each portion in the first cold air guide passage 310 . Accordingly, the cold air discharged to the main cold air discharge unit 110 can be discharged to the space where the upper wall surface of the freezing compartment 12 is located.

In addition, the main cold air discharge unit 110 is formed to have a short height compared to the vertical height of the refrigeration fan module 410, while being longer left and right compared to the left and right width of the refrigeration fan module 410, thereby making the refrigeration fan module 410 longer. Cool air flowing in the circumferential direction of the corresponding refrigerating fan module 410 by rotation of the fan module 410 can be sufficiently discharged into the freezing chamber 12 through the main cold air discharge unit 110 .

In addition, a plurality of grill ribs 111 are formed in the main cold air discharge unit 110 .

The grill ribs 111 are ribs for guiding the discharge direction of the cold air discharged to the main cold air discharge unit 110 .

The above-described grill ribs 111 are disposed to be spaced apart from each other and inclined toward the front or both sides. At this time, the grill ribs on the central side of the grill ribs 111 are formed to face forward, and the grill ribs on both sides are formed to be inclined outwardly to the outside. This structure allows the cold air to be uniformly discharged to all parts of the freezing compartment 12 despite the cold air being discharged to the main cold air discharge unit 110 having a narrow left and right width compared to the left and right widths in the freezing compartment 12 .

Of course, the grill ribs 111 may be more inclined toward the outside as they are positioned outside the main cold air discharge unit 110 so that cold air can be uniformly supplied to a wider space.

In addition, the main cold air discharge unit 110 may be formed of a tubular body protruding forward rather than a simple hole. That is, the cold air passing through the main cold air discharging unit 110 can be given straightness, and thus the cold air passing through the main cold air discharging unit 110 is discharged straight forward without spreading up and down. ), it is possible to supply cold air to the front side of the interior.

On the other hand, the main cold air discharge unit 110 is preferably formed in the uppermost portion of each portion of the grill pan (100). That is, by locating the main cold air discharge unit 110 at the upper side as much as possible, cold air is discharged toward the upper space in the freezing compartment 12 , and the first cold air guide flow path 310 has a flow path of sufficient size to have the corresponding grill It is designed to lower the vertical height of the fan 100 as much as possible.

In addition, the cold air discharging units 110 , 120 and 130 include auxiliary cold air discharging units 120 , 130 .

The auxiliary cold air discharge units 120 and 130 are holes provided to supply cold air to an intermediate space in the freezing compartment 12 . That is, considering that the main cold air discharge unit 110 is configured to supply cold air only to the upper surface side in the freezing compartment 12 , cold air supply may be relatively insufficient to the middle side portion compared to the upper surface side. As a result, the cold air can be supplied to the middle portion in the freezing compartment 12 through the additional provision of the auxiliary cold air discharge units 120 and 130 .

These auxiliary cold air discharge units 120 and 130 may be formed on both sides of the bottom of the main cold air discharge unit 110 among each portion in the first cold air guide passage 310 .

In particular, the auxiliary cold air discharge parts 120 and 130 are formed on the bottom side of the first cold air guide flow path 310 while the cold air flows along the bottom inside the first cold air guide flow path 310. To be discharged to the freezing chamber (12).

That is, the auxiliary cold air discharging units 120 and 130 supply cold air from the bottom of the main cold air discharging unit 110 into the freezing chamber 12, so that the cold air to the middle portion in the freezing chamber 12 can be sufficiently supplied. .

At this time, the auxiliary cold air discharging parts 120 and 130 are formed on any one side (left side in the drawing when the grill pan is viewed from the front) (refer to the attached FIG. 8 ) of the bottom side part in the first cold air guide flow path 310 . The first auxiliary cold air discharge unit 120 and the second auxiliary cold air discharge unit 130 formed on the other side (the right side in the drawing when the grill pan is viewed from the front) (refer to the attached FIG. 8 ) are included. That is, while the cold air flows along the first cold air guide passage 310, it sequentially passes through the first auxiliary cold air discharge unit 120 and the second auxiliary cold air discharge unit 130 to be additionally supplied to the freezing chamber 12. made it possible

In addition, the main cold air discharge unit 110 is formed to be larger than the combined size of the first auxiliary cold air discharge unit 120 and the second auxiliary cold air discharge unit 130 , so that most of the air blown by the freezing fan module 410 . of the cold air is supplied into the freezing chamber 12 through the main cold air discharge unit 110 .

At the same time, a plurality of grill ribs 121 and 131 are formed in the two auxiliary cold air discharge units 120 and 130 .

At this time, each of the grill ribs 121 and 131 has a structure that gives direction to the cold air discharged through the corresponding auxiliary cold air discharge units 120 and 130, and at least some of the grill ribs 121 and 131 allow the cold air passing through the corresponding portion to pass through the freezer compartment ( 12) It is preferable to be inclined so as to be guided toward the inner side.

In particular, the two auxiliary cold air discharge units 120 and 130 may be formed of a tubular body protruding forward.

That is, the cold air passing through the auxiliary cold air discharging units 120 and 130 can be given straightness, and for this reason, the cold air passing through the auxiliary cold air discharging units 120 and 130 does not spread up and down and is discharged straight forward while being discharged in the freezing compartment 12 . It becomes possible to supply cold air to the front side of the inside.

In addition, the grill pan 100 is further provided with a suction guide 140 for guiding the recovery flow of the cold air flowing through the freezing chamber (12). At this time, the suction guide 140 is formed at the lower end of the grill pan 100 and the cold air recovered after circulating in the freezing chamber 12 flows into the lower end of the second evaporator 32 .

In particular, since the machine room 15 is located at the bottom of the rear side (the side where the rear wall surface is located) in the freezing compartment 12, the rear end portion of the bottom surface of the freezing compartment 12 is inclined forward toward the bottom. In consideration of this, it is preferable that the suction guide 140 is inclined at the same (or similar) angle (or round) as the rear end of the bottom of the freezing compartment 12 toward the lower end. That is, the cold air flowing along the bottom of the freezing chamber 12 flows along the slope and is guided by the suction guide 140 so that it can smoothly flow to the lower end of the second evaporator 32 .

In addition, a temperature sensor 150 is installed in the grill pan 100 .

The temperature sensor 150 is a sensor for sensing the temperature in the freezing compartment 120 , and is configured to be located at either end of both ends of the grill pan 100 .

In addition, on the rear surface of the grill pan 100 , the first seating part 160 and the second seating part 170 are respectively recessed (protruding toward the front of the grill pan).

Here, the first seating portion 160 is provided as a portion on which the refrigeration fan module 410 is mounted.

The first seating portion 160 is formed to be recessed from the surface (rear surface) of the grill pan 100 .

That is, the refrigeration fan 411 of the refrigeration fan module 410 seated on the first seating part 160 is spaced apart from the second evaporator 32 located at the rear of the grill fan assembly 1 as far as possible. As a result, the influence (influence of the surface temperature) that the refrigeration fan 411 receives from the second evaporator 32 can be reduced as much as possible.

In addition, the first seating part 160 is located on the upper side compared to the center when viewed based on the height of the grill pan 100 , and when viewed based on the left and right length of the grill pan 100 , approximately formed in the central region.

At this time, the main cold air discharge unit 110 is formed to cross the upper end portion of the first seating unit 160 .

In addition, the depression depth of the first seating part 160 is determined in consideration of the separation distance between the freezing fan 411 of the freezing fan module 410 and the second evaporator 32 . That is, considering that condensed water may be formed when the refrigeration fan 411 is excessively close to the second evaporator 32, the first seating is spaced apart from each other by at least 3 mm. It is desirable to determine the depression depth of the portion 160 .

In addition, the upper surface of the first seating part 160 has a structure that is opened upward.

Accordingly, the cold air flowing between the grill pan 100 and the shroud 200 through the first inlet hole 210 by preventing the first seating part 160 from blocking the main cold air discharge part 110 is the This is so that it can be discharged directly to the main cold air discharge unit 110 .

In addition, the second seating part 170 is formed on the side of the first seating part 160 and is provided as a portion on which the ice making fan module 420 is mounted. That is, the ice-making fan module 420 is installed to be concave from the surface of the grill pan 100 to prevent freezing due to the influence of the second evaporator 32 .

Next, the shroud 200 will be described with reference to FIGS. 4 and 5 and 7 and 10 and 11 attached thereto.

The shroud 200 is a portion forming the rear wall of the grill pan assembly 1 and is located on the rear side of the grill pan 100 . This is as shown in the accompanying Figures 4 and 5.

The shroud 200 is coupled to the rear surface of the grill pan 100 to be spaced apart, and serves to provide a space so that a flow path for cold air flow can be created between the grill pan 100 and the grill pan 100 .

In particular, the first inlet hole 210 and the second inlet hole 220 are formed through the shroud 200 .

At this time, the first inlet hole 210 is formed to be located closer to the upper surface of the shroud 200 than the lower surface in the first cold air guide passage 310 among the central portion of the shroud 200 . The second inlet hole 220 is formed on one side of the first inlet hole 210 .

In addition, a first bell mouth 211 is formed around the first inlet hole 210 and a second bell mouth 221 is formed around the second inlet hole 220 . At this time, the two inlet holes 210 and 220 can introduce the cold air heat-exchanged through the second evaporator 32 located at the rear in the freezing compartment 12 into the space between the grill fan 100 and the shroud 200 . A hole formed so that

In addition, the first bell mouse 211 is designed in consideration of the amount of air supplied to the freezing chamber 12 through the freezing fan module 410 , and the second bell mouse 221 is the ice-making fan module 420 . ) and is designed in consideration of the pressure of the cold air supplied to the ice making chamber 21 .

That is, the freezing fan module 410 is configured to supply a sufficient amount of cold air because it supplies cold air to the freezing chamber 12 located in front thereof, whereas in the case of the ice-making fan module 420, the refrigerator compartment door 20 Since it is a configuration that supplies cold air to the ice-making chamber 21 located in the

Considering this, in the case of the second bell mouse 221, it is suggested that a shielding member 222 is additionally formed on its inner circumferential surface. That is, each impeller 421a of the ice-making fan 421 constituting the ice-making fan module 420 is maximally covered by the shielding member 222 so that it passes through the second inlet hole 220 to assemble the grill pan assembly. The cold air introduced into the second cold air guide flow path 320 in (1) is not discharged through the second inlet hole 220 again, but the blowing pressure is further increased to make it more smoothly pressurized.

On the other hand, the shroud 200 is formed to block the main cold air discharge unit 110 and the two auxiliary cold air discharge units 120 and 130 of the grill pan 100 while blocking the suction guide 140 of the grill pan 100 . It is designed not to be obstructed.

That is, the shroud 200 is formed to block only a part of the rear surface of the grill pan 100 so that the grill pan assembly 1 can be made compact and cool air flows smoothly, and the suction guide 140 . The cold air recovered by the guidance of the second evaporator 32 is to be able to flow smoothly to the lower end.

In particular, the grill pan 100 and the shroud 200 are formed to have upper surfaces 103 and 203, respectively, and the upper surfaces 103 and 203 are coupled to each other in an overlapping state.

Next, the first cold air guide flow path 310 will be described with reference to FIGS. 8 and 9 .

The first cold air guide passage 310 guides the cold air introduced between the grill pan 100 and the shroud 200 through the first inlet hole 210 to flow into the freezing chamber 12 and the switching chamber 13 . is the euro

The first cold air guide flow path 310 is formed on at least one of the opposing surfaces between the grill pan 100 and the shroud 200 .

In one embodiment of the present invention, it is assumed that the first cold air guide passage 310 is formed on the rear surface of the grill pan 100 . In particular, the first cold air guide passage 310 is formed to protrude forward from the rear surface of the grill pan 100 so that cold air can flow along the inside thereof.

At this time, the rear surface of the first cold air guide passage 310 (the surface facing the rear of the grill pan) is formed to be open, but the shroud 200 is closely coupled to the rear surface of the grill pan 100 to guide the first cold air. The flow path 310 may provide a flow path blocked from the external environment.

Of course, although not shown, the first cold air guide flow path 310 may be formed on the front surface of the shroud 200 , and after being manufactured separately from the grill pan 100 or the shroud 200 , the grill It may be configured to be coupled between the pan 100 and the shroud 200 , and may be formed in portions in the grill pan 100 and the shroud 200 .

In addition, the first cold air guide flow path 310 surrounds the periphery of the first seating part 160 from the portion where the first seating part 160 is formed, and the end of the first seating part 160 is either side of the first seating part 160 . (The side of the side opposite to the side where the second seating part is located) is formed to be rounded toward the top.

That is, the first cold air guide passage 310 is formed in a rounded structure along the flow direction of the cold air by the rotation of the freezing fan 411 so that cold air can flow smoothly along the first cold air guide passage 310 . did it

In particular, the end of the first cold air guide passage 310 is formed to be open to the upper surfaces of the grill pan 100 and the shroud 200 . That is, by allowing the first cold air guide passage 310 to be opened to the upper portion of the grill fan assembly 1, the connection with the conduit (eg, cold air duct for a switching room) connected to the first cold air guide passage 310 is connected to the upper portion. In this way, it is possible to avoid the problem of reducing the storage space as the front and rear depth in the freezing compartment 12 is shortened because the connection part is made to face upward in this way.

At this time, the lower end of the cold air duct 41 for the changeover room for supplying cold air to the changeover chamber 13 located above the freezing chamber 12 is connected to the open end of the first cold air guide flow path 310 (attached) 12 to 14)). The upper end of the cold air duct 41 for the switching room is connected to the rear surface of the switching room 13 (see attached FIG. 5).

Meanwhile, the two auxiliary cold air discharge units 120 and 130 for discharging cold air to the freezing chamber 12 are formed along the bottom surface of the first cold air guide passage 310 .

That is, the cold air can be sequentially discharged to the freezing chamber 12 through the two auxiliary cold air discharge units 120 and 130 while the cold air flows along the first cold air guide passage 310 .

In particular, the two auxiliary cold air discharge units 120 and 130 are respectively formed on both sides of the bottom side space in the first cold air guide passage 310 . This is because the portion between the two auxiliary cold air discharge units 120 and 130 is actually a portion facing the lower space in the freezing compartment 12, so if the auxiliary cold air discharge units 120 and 130 are formed in this area, the auxiliary cold air discharge units 120 and 130 are formed. This is because the cold air discharged through the circulating in the freezing chamber 12 and colliding with the cold air flow recovered to the lower space may be concerned.

On the other hand, as shown in FIG. 13 , a flow path opening/closing module 330 is further provided in the first cold air guide flow path 310 .

* The flow path opening/closing module 330 is configured to open and close to selectively block the cool air flowing along the first cold air guide flow path 310 from being discharged to the cold air outlet side of the first cold air guide flow path 310 .

That is, the cold air supplied to the switching chamber 13 along the first cold air guide passage 310 by the passage opening/closing module 330 can be interrupted as necessary. Through this, the inside of the switching chamber 13 can store the stored material under a different temperature condition than that of the freezing chamber 12 .

The flow path opening/closing module 330 is installed to block the first cold air guide flow path 310 .

Preferably, a mounting end 311 that is expanded compared to other parts is formed in the first cold air guide flow path 310, and heat insulation and accurate mounting of the flow path opening/closing module 330 are performed in the mounting end 311. is provided with a mounting cover 350 (refer to attached FIG. 7) for the purpose, and the flow path opening/closing module 330 is provided into the mounting end 311 in a state of being mounted in the mounting cover 350, and cold air passing through the corresponding part is provided. designed to block the flow of

At this time, the mounting end 311 projects a portion of the portion where the first cold air guide passage 310 of the grill fan 100 is formed forward compared to other portions, and the first cold air guide passage of the shroud 200 . Some of the parts blocking the 310 are formed to protrude backward compared to other parts.

The mounting end 311 is positioned adjacent to the cold air outlet side of the first cold air guide passage 310 .

In particular, the mounting end 311 is preferably formed to be inclined.

Of course, the mounting end 311 may be formed horizontally or vertically. However, when the mounting end 311 is formed horizontally to the left and right, it is difficult to remove it when the condensate is generated as the flow path opening/closing module 330 mounted thereon is laid down horizontally, and the mounting end 311 is moved up and down. When formed vertically, as the flow path opening/closing module 330 mounted thereon is vertically erected, there is a fear that the flow path may not be closed correctly.

The flow path opening/closing module 330 is configured to include a damper case 331 , an opening/closing damper 332 , and a damper operation unit 333 as shown in FIGS. 15 to 18 .

Here, the damper case 331 is installed to block the inside of the mounting end 311 and has a rectangular frame structure in which a through hole 331a is formed inside, and the opening/closing damper 332 is the damper case 331 ) is installed to open and close the through hole 331a, and the damper operation unit 333 operates the opening/closing damper 332.

At this time, the damper operation unit 333 may be a motor, and the opening/closing damper 332 may be formed of a plate that blocks or opens the through hole 331a while rotating while being shaft-coupled to the motor. .

Of course, although not shown, the flow path opening/closing module 330 may be configured to forcibly block or open the first cold air guide flow path 310 by a solenoid or a cylinder, etc. can

Next, the second cold air guide flow path 320 will be described with reference to FIGS. 8 and 9 attached thereto.

The second cold air guide passage 320 is a passage for guiding the cold air introduced between the grill pan 100 and the shroud 200 through the second inlet hole 220 to flow into the ice making chamber 21 .

The second cold air guide passage 320 is formed on at least one of the opposite surfaces between the grill pan 100 and the shroud 200 .

In one embodiment of the present invention, the second cold air guide passage 320 is formed to be recessed in the rear surface of the grill pan 100 so that cold air can flow along the inside thereof.

At this time, the rear surface of the second cold air guide passage 320 is opened, and the rear surface of the opened second cold air guide passage 320 is closed from the external environment by the shroud 200 .

Of course, although not shown, the second cold air guide passage 320 may be formed in the shroud 200 , and in this case, the second cold air guide passage 320 is removed from the external environment by the grill fan 100 . is closed

Although not shown, the second cold air guide flow path 320 is manufactured separately from the grill pan 100 or the shroud 200 and is configured to be coupled between the grill pan 100 and the shroud 200 . could be

The second cold air guide passage 320 is formed around the periphery of the second seating portion 170 until the end reaches the side of the grill pan 100 .

At this time, the end of the second cold air guide passage 320 is formed to be opened to pass through the side surface of the grill pan 100 .

One end of the cold air duct 51 for the ice-making chamber that supplies cold air to the ice-making chamber 21 is connected to the open end of the second cold air guide passage 320 . The other end of the cold air duct 51 for the ice-making chamber is connected to a guide duct 22 that supplies cold air to the ice-making chamber 21 .

In particular, the second cold air guide passage 320 is formed such that the passage gradually becomes narrower toward the cold air outlet side. This increases the flow pressure of the cold air so that the cold air can be supplied to a more distant location.

In addition, the second seating portion 170 on which the ice-making fan module 420 is seated is formed in the second cold air guide passage 320 .

In this case, the second seating part 170 is located at an end opposite to one end of the second cold air guide flow path 320 , at which the cold air outlet side of the second cold air guide flow path 320 is located. Accordingly, the second cold air guide passage 320 has the longest length as possible.

On the other hand, on the rear surface of the grill pan 100 and the front surface of the shroud 200, the contact portions 102 and 202 (Figs. 9 and 10) along the first cold air guide passage 310 and the second cold air guide passage 320. see) may be formed respectively.

At this time, the respective contact portions 102 and 202 are positioned to face each other. At the same time, each of the contact portions 102 and 202 is formed of a concave portion and a protrusion portion engaged with each other.

These close contact portions 102 and 202 are in close contact with each other (or engage) when the grill pan 100 and the shroud 200 are coupled, and the first cold air guide flow path 310 and The inside of the second cold air guide passage 220 may be sealed from the external environment.

Next, the refrigeration fan module 410 will be described with reference to FIGS. 19 to 24 attached thereto.

The refrigeration fan module 410 is configured to blow the cold air that has passed through the second evaporator 32 to the first cold air guide passage 310 .

The refrigeration fan module 410 includes a refrigeration fan 411 and a first installation frame 412 .

Here, the refrigeration fan 411 is formed as a slim centrifugal fan so that the thickness (front-rear direction width) of the grill fan assembly 1 can be reduced as much as possible.

In addition, the first installation frame 412 is a portion where the refrigeration fan 411 is installed.

The first installation frame 412 is configured to be fastened to the grill pan 100 using a plurality of fastening ribs 412a, 412b, and 412c. At this time, each of the fastening ribs 412a, 412b, and 412c is formed at a position in consideration of the size and wind direction of the freezing fan 411, respectively.

Next, the ice making fan module 420 will be described with reference to FIGS. 19 and 20 to 24 attached thereto.

The ice-making fan module 420 is configured to blow the cold air that has passed through the second evaporator 32 to the second cold air guide passage 320 .

The ice-making fan module 420 includes an ice-making fan 421 and a second installation frame 422 .

Here, the ice-making fan 421 is formed as a slim centrifugal fan, so that the thickness (front-rear direction width) of the grill fan assembly 1 can be reduced as much as possible.

In particular, the ice making fan 421 is provided as a fan having the same structure and size as the freezing fan 411 of the freezing fan module 410 . That is, the two blowing fans 411 and 421 can be used in common.

In addition, the second installation frame 422 is a portion where the ice-making fan 421 is installed.

The second installation frame 422 is configured to be fastened to the grill pan 100 using a plurality of fastening ribs 422a, 422b, and 422c. In this case, each of the fastening ribs 422a, 422b, and 422c is formed at a position in consideration of the size and wind direction of the ice-making fan 421, respectively.

In particular, the ice-making fan module 420 is configured to be located closer to the flow path ribs 510 and 520 (see attached FIG. 21 ) compared to the cold air outlet side of the second cold air guide flow path 320 . That is, by allowing the ice making fan 421 of the ice making fan module 420 to be spaced apart from the cold air outlet side of the second cold air guide flow path 320 by a sufficient distance, the cold air outflow of the second cold air guide flow path 320 . This is to prevent the phenomenon that the cold air passing through the side does not pass smoothly through the cold air outlet side due to resistance due to the flow of the cold air rotated along the rotational direction of the ice making fan 421 and turbulence occurs. In this case, it is preferable to set the separation distance between the ice-making fan module 420 and the cold air outlet side to be at least 25 mm or more.

In addition, the ice-making fan 421 constituting the ice-making fan module 420 is configured to rotate at a higher rotational speed than the freezing fan 411 constituting the freezing fan module 410 .

That is, the freezing fan 411 rotates at a rotational speed sufficient to provide a high air volume because cold air is supplied to the freezing chamber 12 in front thereof, but in the case of the ice-making chamber 21, the freezing chamber 12 or Since it is located relatively far from the switching chamber 13, the ice-making fan 421 operates at a higher rotational speed than the freezing fan 411 and pressurizes air to the ice-making chamber 21. will be.

Next, the flow path ribs 510 and 520 will be described with reference to FIGS. 9 and 25 .

The flow path ribs 510 and 520 are formed to cross the boundary between the first cold air guide flow path 310 and the second cold air guide flow path 320 to partition the two cold air guide flow paths 310 and 320 from each other.

The flow path ribs 510 and 520 are configured to include a first circumferential side flow path rib 510 and a second circumferential side flow path rib 520 .

Here, the first circumferential flow path rib 510 is formed to protrude downward from the upper surface 103 of the grill pan 100 .

That is, the first circumferential flow path rib 510 blocks the upper portion from the central portion between the ice-making fan module 420 and the freezing fan module 410 .

Due to the structure of the first circumferential flow path rib 510 , the cold air provided from the refrigeration fan module 410 is prevented from being discharged directly to the cold air outlet side of the second cold air guide passage 320 .

In this case, the lower end of the first circumferential flow path rib 510 has a length reaching a lower position than the central positions of the freezing fan module 410 and the ice making fan module 420 . Through this, the cold air provided from the freezing fan module 410 minimizes the flow to the side where the ice-making fan module 420 is located, and the cold air by the operation of the ice-making fan module 420 is the main cold air in the first cold air guide passage 310 . This is so that it can be smoothly supplied toward the discharge unit 110 .

In particular, the first circumferential side flow path rib 510 is formed to be rounded to surround a portion of the circumference of the second seating portion 170 .

That is, the cold air blown from the ice-making fan module 420 through the round structure of the first circumferential side flow path rib 510 can smoothly flow to the cold air outlet side of the second cold air guide flow path 320 , and also, the The cold air blown from the refrigeration fan module 410 through the round structure of the first circumferential flow path rib 510 passes between the refrigeration fan module 410 and the ice-making fan module 420, and the first cold air guide flow path 310 It is designed to flow smoothly into the bottom of the inner body.

In addition, the second circumferential flow path rib 520 is formed to protrude upward from the bottom surface in the first cold air guide flow path 310 among the rear surfaces of the grill pan 100 .

That is, the second circumferential flow path rib 520 blocks the lower portion from the central portion between the ice-making fan module 420 and the freezing fan module 410 .

By the structure of the second circumferential flow path rib 520 , the cold air provided from the ice making fan module 420 is prevented from being directed to the freezing fan module 410 in the first cold air guide flow path 310 , while the main cold air discharge unit ( 110) to be able to flow smoothly.

In this case, the upper end of the second circumferential flow path rib 520 is formed to have a length reaching a higher position than the central positions of the freezing fan module 410 and the ice making fan module 420 . Through this, the cold air provided from the freezing fan module 410 minimizes the flow to the side where the ice-making fan module 420 is located, and the cold air by the operation of the ice-making fan module 420 is the main cold air in the first cold air guide passage 310 . This is so that it can be smoothly supplied toward the discharge unit 110 .

In addition, the second circumferential side flow path rib 520 is formed to be rounded to surround a portion of the circumference of the second seating portion 170 .

That is, the cold air blown from the ice-making fan module 420 through the round structure of the second circumferential flow path rib 520 is one end portion of the main cold air discharge unit 110 (the side portion where the ice-making fan module is located). ) so that it can flow smoothly.

In particular, a guide rib 521 (see attached FIG. 25 ) is formed at the lower end portion of the second circumferential flow path rib 520 .

At this time, the guide rib 521 gradually protrudes toward the bottom of the first cold air guide flow path 310 toward the lower end of the second circumferential side flow path rib 520 , and any of the bottom surfaces within the first cold air guide flow path 310 . It is formed to be round so that cold air flows to one end.

That is, the cold air flowing downward along the surface of the second circumferential side flow path rib 520 is guided by the guide rib 521 and is located on one side of the bottom surface in the first cold air guide flow path 310 . 1 It is designed so that it can flow smoothly to the auxiliary cold air discharge part 110 .

In addition, the lower end of the first circumferential flow path rib 510 and the upper end of the second circumferential side flow path rib 520 are formed to be spaced apart from each other. At this time, the spaced portion is provided as a common passage (G). That is, the shared flow path G is formed by separating the two circumferential flow path ribs 510 and 520 apart from each other, and the second cold air guide flow path blown by the ice-making fan module 420 through the shared flow path G. The cold air in the 320 may be partially supplied into the first cold air guide passage 310 .

At this time, the lower end of the first circumferential side flow path rib 510 is disposed to be positioned relatively closer to the ice making fan module 420 than the upper end of the second circumferential side flow path rib 520 , and the second The upper end of the circumferential flow path rib 520 is formed to be positioned higher than the lower end of the first circumferential flow path rib 510 . The separation and overlapping structure of the two circumferential flow path ribs 510 and 520 is such that the cold air blown by the ice-making fan module 420 can be smoothly supplied to the freezing chamber 12 through the main cold air discharge unit 110 .

In particular, the sharing flow path (G) is formed to face either end of the main cold air discharge unit (110). As a result, it is possible to reduce the phenomenon that the cold air supplied to the main cold air discharge unit 110 through the shared passage G collides with and interferes with the cold air flowing in the first cold air guide passage 310 .

On the other hand, when the refrigeration fan module 410 is operated in a state in which the ice-making fan module 420 is stopped (or when the ice-making fan module is stopped while the refrigeration fan module is operating), through the shared flow path (G) The cold air in the first cold air guide passage 310 may be supplied into the second cold air guide passage 320 . Accordingly, there is a concern that the amount of cold air supplied to the freezing chamber 12 is insufficient.

In consideration of this, the ice-making fan module 420 guides the first cold air while allowing the cold air flowing in the second cold air guide passage 320 to be smoothly supplied into the first cold air guide passage 310 through the shared passage G. It is preferable to reduce the supply of cold air flowing in the flow path 310 into the second cold air guide flow path 320 through the shared flow path G (hereinafter, referred to as “reverse flow”).

A configuration for reducing such reverse flow may be made in various ways.

For example, at least one of the fastening ribs 412a, 412b, and 412c constituting the first installation frame 412 in consideration of the flow of cold air by the freezing fan 411 of the refrigerating fan module 410 (hereinafter, “ It is possible to reduce the reverse flow by locating a fastening rib for shielding” (412a).

That is, by locating the locking rib 412a for occlusion in the portion facing the shared flow path G among the flow paths of the cold air flowing while turning around the refrigeration fan 411, the flow of the cold air is reduced by the locking rib ( 412a) to prevent direct flow to the shared passage (G).

In addition, the flow guide end 161 for guiding the flow of cold air is formed in the first seating part 160 on which the refrigeration fan module 410 is seated, thereby reducing the reverse flow.

That is, the flow of cold air flowing while turning around the refrigeration fan 411 of the refrigeration fan module 410 is guided by the flow guide end 161 toward either side of the main cold air discharge unit 110 . This is to reduce the reverse flow by inducing them to do so.

At this time, the flow guide end 161 is formed to be inclined outwardly or rounded from one end of the first seat 160 , which is located adjacent to the second seat 170 , among both ends of the upper surface.

And, among the respective fastening ribs 422a, 422b, and 422c provided in the second installation frame 422 of the ice-making fan module 420, two fastening ribs (a fastening rib for the first compartment and a fastening rib for the second compartment) 422a , 422b) may be installed to be positioned adjacent to the first circumferential side flow path rib 510 and the second circumferential side flow path rib 520, respectively, to reduce the reverse flow.

That is, while the fastening ribs 422a and 422b for the two compartments are positioned adjacent to the first circumferential side flow path rib 510 and the second circumferential side flow path rib 520, respectively, the first compartment fastening rib 422a and adjacent thereto The gap G1 between the first circumferential flow path rib 510 and the gap G2 between the second compartment fastening rib 422b and the second circumferential flow path rib 520 adjacent thereto are minimized. . This is as shown in the attached FIG. 25 .

Accordingly, even if the cold air in the first cold air guide passage 310 flows into the second cold air guide passage 320 through the shared passage G between the two circumferential passage ribs 510 and 520 , the cold air thus introduced is the second Flow to the cold air outlet side of the cold air guide flow path 320 (a portion where cold air is discharged into the ice making chamber) may be prevented or minimized.

Of course, although not shown or described, it is possible to reduce the reverse flow in addition to the flow guide end 161 or the fastening ribs 412a for shielding and the fastening ribs 422a and 422b for the two compartments of the first installation frame 412. Various configurations in which there may be additionally provided.

Meanwhile, the grill pan 100 may further include a straight-side flow path rib 530 in addition to the two two-body side flow path ribs 510 and 520 described above.

The straight-side flow path rib 530 is formed from an end of the second circumferential side flow path rib 520 (an end opposite to the side on which the first circumferential side flow path rib is positioned) from one side of the corresponding grill pan 100 (for an ice-making chamber). It is formed up to the connection part with the cold air duct).

That is, the cold air flowing in the circumferential direction along the two circumferential flow path ribs 510 and 520 by the straight flow path rib 530 can flow toward the cold air duct 51 for the ice-making chamber.

At this time, the straight-side flow path rib 530 may be formed as a rib protruding from the surface of the grill pan 100 , and as shown in the embodiment, the edge portion of the grill pan 100 is bent (recessed or depressed). , protrusion) may be formed.

Hereinafter, the temperature control process of each of the storage compartments 12 , 13 , and 21 by the operation of the grill pan assembly 1 according to the embodiment of the present invention described above will be described in more detail.

First, a process for controlling the temperature of the freezing compartment 12 will be described with reference to FIGS. 26 to 28 attached thereto.

The temperature control of the freezing chamber 12 is performed by the operation of the freezing fan module 410 and the compressor (not shown). That is, the operation for controlling the temperature of the freezing chamber 12 is performed by the rotation of the refrigerating fan 411 by the supply of power to the refrigerating fan module 410 and the heat exchange operation of the second evaporator 32 by the operation of the compressor. .

At this time, if the cold air supply to the switching chamber 13 is not required during operation for controlling the temperature of the freezing chamber 12, the opening/closing damper 332 constituting the flow path opening/closing module 330 has a through hole 331a of the damper case 331. ), so that the cold air outlet side of the first cold air guide flow path 310 is maintained in a closed state.

And, when the freezing fan 411 of the freezing fan module 410 is operated, the air in the freezing compartment 12 flows through the second evaporator 32 by the air blowing force by the freezing fan 411, It is heat-exchanged while passing through the second evaporator 32 .

In addition, the heat-exchanged air (cold air) passes through the first inlet hole 210 of the shroud 200 and flows into the first cold air guide passage 310 and then along the first cold air guide passage 310. It flows and is continuously supplied to the upper space in the freezing chamber 12 through the main cold air discharge unit 110 formed in the grill pan 100 .

At the same time, the remaining cold air that has not yet been discharged to the main cold air discharge unit 110 among the cold air flowing by the blowing force by the refrigeration fan 411 flows along the first cold air guide passage 310 , and in this way, the first While flowing along the cold air guide flow path 310, it sequentially passes through the first auxiliary cold air discharge unit 120 and the second auxiliary cold air discharge unit 130 formed in the first cold air guide flow path 310. supplied to the middle side.

At this time, about half or more of the cold air that has passed through the first inlet hole 210 is discharged to the main cold air discharge unit 110 , and the remaining cold air is the first auxiliary cold air discharge unit 120 and the second auxiliary cold air discharge unit. (130) is discharged.

In particular, considering that the cold air outlet side of the first cold air guide passage 310 is closed by the passage opening/closing module 330 , the cold air flowing in the first cold air guide passage 310 is each auxiliary cold air. Most of it is supplied to the intermediate space in the freezing compartment 12 through the discharge units 120 and 130, and a portion is supplied to the portion where the upper surface of the freezing compartment 12 is located through the main cold air discharge unit 110 while rising again.

Of course, some of the cold air that is not discharged to the main cold air discharge unit 110 and flows downward along the first cold air guide passage 310 is generated in the same direction as the rotation direction of the freezing fan 411 by the flow of cold air. It may flow into the second cold air guide flow path 320 through the shared flow path G between the two circumferential flow path ribs 510 and 520 .

However, the flow of cold air generated in the same direction as the rotational direction of the refrigeration fan 411 is a flow guide end 161 formed in the first seating part 160 and the first installation frame of the refrigeration fan module 410 ( 412) is blocked by the fastening ribs 412a for occlusion and is prevented from flowing directly into the shared flow path G between the two circumferential side flow path ribs 510 and 520. At this time, the cold air is guided to the end side of the main cold air discharge unit 110 by the inclined (or round) structure of the flow guide end 161 . The flow of cold air is as shown in FIG. 29 .

Of course, among the cold air flowing from the upper surface in the first cold air guide passage 310 to the lower surface in the first cold air guide passage 310 , some of the cold air flowing along the surfaces of the two circumferential side passage ribs 510 and 520 is the second cold air guide It may flow into the flow path 320 .

However, the cold air flowing into the second cold air guide passage 320 is only a part of the cold air flowing in the first cold air guide passage 310 , and most of the cold air circulates in the first cold air guide passage 310 .

Accordingly, the amount of cold air flowing into the second cold air guide passage 320 is supplied to the freezing chamber 12 through the main cold air discharge unit 110 and the two auxiliary cold air discharge units 120 and 130 in the first cold air guide passage 310 . It is very insignificant compared to the amount of cold air to be used, so it does not substantially affect the temperature control of the freezing compartment 12 . Furthermore, in the case of cold air flowing into the second cold air guide flow path 320 while flowing in the first cold air guide flow path 310, the first circumferential side flow path rib 510 and the second circumferential side flow path rib 520, respectively. Due to the fastening ribs 422a and 422b for two compartments of the second installation frame 422 positioned adjacent to each other, the cold air in the second cold air guide flow path 320 cannot flow to the outflow side and again between the two circumferential flow path ribs 510 and 520. It flows into the first cold air guide passage 310 through the shared passage (G) of the.

On the other hand, the cold air flowing in the first cold air guide passage 310 is guided by the flow of the first cold air guide passage 310 as well as the upper and lower surfaces of the first cold air guide passage 310 by the circumferential flow passage ribs 510 and 520 .

* That is, some of the cold air flowing down through the main cold air discharge unit 110 while flowing along the upper surface in the first cold air guide flow path 310 flows along the surface of the second circumferential side flow path rib 520, and its In the process, it is guided by the guide rib 521 formed at the lower end portion of the second circumferential flow path rib 520 and flows to the portion where the first auxiliary cold air discharge unit 120 is formed.

Accordingly, the cold air flowing under the guidance of the guide rib 521 is supplied into the freezing chamber 12 through the first auxiliary cold air discharge unit 120 .

Subsequently, the cold air that cannot be discharged to the first auxiliary cold air discharge unit 120 and passes through it flows along the bottom surface in the first cold air guide passage 310 and flows to the second auxiliary cold air discharge unit 130 , and the second It is discharged into the freezing chamber 12 through the auxiliary cold air discharge unit (130).

In particular, since the bottom surface in the first cold air guide passage 310 is formed to be round, the cold air passing through the first auxiliary cold air discharge unit 120 is removed while flowing along the bottom surface of the first cold air guide passage 310 . It can flow smoothly to the second auxiliary cold air discharge unit 130 .

The flow of cold air during the freezing operation of the freezing compartment 12 is as shown in FIGS. 27 and 28 attached thereto.

On the other hand, the accompanying FIG. 29 shows the temperature state according to the flow of cold air during the freezing operation. That is, the cold air flowing backward from the first cold air guide flow path 310 to the second cold air guide flow path 320 through the shared flow path G between the two circumferential side flow path ribs 510 and 520 during independent operation of the cooling fan 411 is It can be seen that it is insignificant, and it can be seen that the cold air flows in the rotational direction according to the operation of the freezing fan 411 and is guided by the two circumferential flow path ribs 510 and 520 .

In addition, the cold air supplied into the freezing chamber 12 through each of the cold air discharge units 110 , 120 , 130 flows in the freezing chamber 12 and then is guided by the suction guide 140 formed in the grill fan 100 , the second evaporator It is recovered to the air inlet side of (32).

In particular, considering that the suction guide 140 is formed to be inclined (or round) of the freezing chamber 12 , the cold flowing along the inclined wall of the machine room 15 after flowing in the freezing chamber 12 is the suction guide Under the guidance of 140, it can flow smoothly to the air inlet side of the second evaporator 32 .

And, while the freezing operation of supplying cold air to the freezing chamber 12 is performed, the temperature in the freezing chamber 12 is continuously checked by the temperature sensor 150 installed in the grill fan 100, and through this, the freezing chamber 12 ), when it is confirmed that the temperature within the set temperature is lower than the set temperature (if the set temperature condition is satisfied), the operation of the refrigerating fan 411 and the refrigerating cycle is stopped and the cold air supply is stopped.

Of course, if the temperature in the freezing compartment 12 is higher than the set temperature, the cooling fan 411 and the refrigerating cycle are operated again to supply cold air into the freezing compartment 12 .

Accordingly, the temperature in the freezing chamber 12 is controlled by the repeated circulation operation of the above-described air (cold air).

Meanwhile, while the temperature control of the above-described freezing compartment 12 is being performed, the ice making fan module 420 may also be operated.

That is, in the case of the ice-making operation, considering that the ice-making fan 421 is always set to operate except under special conditions (eg, when the ice-making chamber is full of ice, etc.), the continuous ice-making operation can be performed even while the freezing operation is being performed. have.

As such, if the ice-making operation is also performed while the freezing operation is being performed, the flow of cold air sequentially passing through the second inlet hole 220 and the second cold air guide passage 320 is generated by the operation of the ice-making fan module 420 . .

As described above, among the cold air generated in the second cold air guide flow path 320, the cold air generated between the two compartment fastening ribs 422a and 422b and the two circumferential side flow path ribs 510 and 520 is the two circumferential side flow path ribs 510 and 520. It flows into the first cold air guide passage 310 through the shared passage (G) between the liver.

In particular, the cold air is discharged toward the main cold air discharge unit 110 by being guided by the rounded end of the first circumferential side flow path rib 510 and the second circumferential side flow path rib 520 .

Accordingly, a sufficient amount of cold air may be supplied into the freezing chamber 12 .

Of course, the cold air flowing to the main cold air discharge unit 110 through the shared flow path G between the two circumferential flow path ribs 510 and 520 is performed by the refrigeration fan 411 in the first cold air guide flow path 310 . They may collide with the swirling flow of cold air and interfere with each other.

However, due to a structure that reduces reverse flow, such as the flow guide end 161 formed in the first seating part 160 and the fastening rib 412a for shielding of the freezing fan module 410, it passes through the shared flow path (G). Direct collision of the cold air and the cold air swirled by the freezing fan 411 is prevented, thereby minimizing flow interference.

The flow of cold air when the freezing operation and the ice making operation are simultaneously performed is shown in FIGS. 30 and 31 .

Next, a process for controlling the temperature of the switching chamber 13 will be described with reference to FIGS. 32 to 34 attached thereto.

The temperature control of the switching chamber 13 is performed by the operation of the refrigeration fan module 410 and the compressor and the operation of the flow path opening/closing module 330 .

That is, the operation for controlling the temperature of the switching chamber 13 is performed by the rotation of the refrigeration fan 411 by the supply of power from the refrigeration fan module 410 and the heat exchange operation of the second evaporator 32 by the operation of the compressor. At this time, the flow path opening/closing module 330 is operated such that the opening/closing damper 332 opens the through hole 331a of the damper case 331 by the operation of the damper operation unit 333 .

And, when the refrigerating fan 411 is operated, the air existing in the rear side of the freezing chamber 12 is heat-exchanged while passing through the second evaporator 32 by the air blowing force by the refrigerating fan 411 .

In addition, the heat-exchanged air (cold air) passes through the first inlet hole 210 of the shroud 200 and then flows into the first cold air guide passage 310 formed in the grill fan 100, and then the first cold air It flows along the guide flow path 310 and is continuously supplied to the upper surface side of the freezing chamber 12 through the main cold air discharge unit 110 formed in the grill pan 100 .

At the same time, the remaining cold air that has not yet been discharged to the main cold air discharge unit 110 among the cold air flowing by the blowing force by the refrigeration fan 411 flows along the first cold air guide passage 310 , and thus While flowing along the cold air guide flow path 310, it sequentially passes through the first auxiliary cold air discharge unit 120 and the second auxiliary cold air discharge unit 130 formed in the first cold air guide flow path 310. In addition to being supplied to the intermediate side, all the remaining cool air passes through the through hole 331a of the damper case 331 located at the mounting end 311 of the first cold air guide flow path 310 and is connected to the cold air outlet side. It is supplied to the switching chamber 13 through the practical cold air duct 41.

At this time, the cold air discharged to the main cold air discharge unit 110 through the first inlet hole 210 is discharged in a relatively small amount compared to the state in which the first cold air guide passage 310 is closed, and the first auxiliary cold air The cold air discharged to the discharge unit 120 and the second auxiliary cold air discharge unit 130 is discharged in a smaller amount compared to the cold air supplied to the switching chamber 13 . Accordingly, cold air can be sufficiently supplied to the switching chamber 13 as well.

Then, the cold air supplied into the change-over chamber 13 by the above process flows in the change-over chamber 13, and then receives the guidance of the return duct 42 for the change-over room connected to the change-over chamber 13 to the second evaporator ( 32) is returned to the air inlet side.

At this time, the cold air duct 41 for the change-over room is connected to the upper side of the rear wall of the change-over room 13 and the return duct 42 for the change-over room is connected to the lower side of the rear wall of the change-over room 13. After the air introduced into the chamber 13 sufficiently flows in the change-over chamber 13, it is discharged through the return duct 42 for the change-over chamber.

Meanwhile, the temperature control of the inside of the switching room 13 may be performed using a temperature sensor for the switching room (not shown). At this time, the temperature sensor for the switching room is configured to sense the temperature in the switching room 13 while being exposed to the inside of the switching room 13 .

Accordingly, the temperature in the switching chamber 13 is controlled by the repeated circulating operation of the above-described air (cold air).

Next, an operation (ice-making operation) for temperature control of the ice-making chamber 21 will be described with reference to FIGS. 35 to 38 .

The temperature control of the ice-making chamber 21 is performed by the operation of the ice-making fan 421 by supplying power to the ice-making fan module 420 . At this time, the compressor may be operated or stopped according to the operating conditions of the freezing compartment 12 .

And, when the ice-making fan 421 is operated, the air existing in the freezing compartment 12 passes through the second evaporator 32 by the air blowing force by the ice-making fan 421 and then the second inflow of the shroud 200 . It passes through the ball 220 and flows into the second cold air guide passage 320 , and continues to flow along the second cold air guide passage 320 .

If the compressor is in operation, the air passing through the second evaporator 32 is further cooled while exchanging heat with the second evaporator 32 .

In addition, the cold air flowing along the second cold air guide passage 320 is provided to the cold air duct 51 for the ice-making chamber connected to the second cold air guide passage 320, and the cold air duct 51 for the ice-making chamber is continuously connected to the second cold air guide passage 320. As it flows along, it is supplied to the ice making chamber 21 .

Accordingly, water (or other beverages) existing in the ice tray (not shown) in the ice-making chamber 21 is frozen by the cold air supplied into the ice-making chamber 21 .

Then, the cold air flowing in the ice-making chamber 21 flows to the ice-making chamber recovery duct 52 , and is subsequently recovered into the freezing chamber 12 under the guidance of the ice-making chamber recovery duct 52 . This is as shown in the accompanying Figures 37 and 38.

Thereafter, the cold air recovered to the freezing chamber 12 flows in the freezing chamber 12 and is guided by the suction guide 140 formed in the grill fan 100 to the air inlet side of the second evaporator 32 . .

If the temperature in the ice-making chamber 21 is lower than the set temperature, the operation of the ice-making fan 421 is stopped and the supply of cold air to the ice-making chamber 21 is stopped.

Accordingly, the temperature in the ice-making chamber 21 is controlled by the repeated circulating operation of the above-described air (cold air).

On the other hand, while cold air is supplied to the ice-making chamber 21 along the second cold air guide flow path 320 by the operation of the ice-making fan 421, a part of the cold air is discharged to the main cold air discharge unit 110 while the freezing chamber ( 12) is supplied. In relation to this, it is the same as mentioned through the description when the ice-making operation is simultaneously performed during the above-described freezing operation.

As a result, in the refrigerator of the present invention, the first cold air guide passage 310 and the second cold air guide passage 320 of the grill fan assembly 1 are formed to communicate with each other, so that the freezing fan 411 and the ice making fan 421 are connected to each other. Even if they are simultaneously operated, sufficient cold air may be supplied to the freezing chamber 12 .

In addition, in the refrigerator of the present invention, when the freezing fan 411 and the ice making fan 421 are operated, the first cold air guide flow path 310 passes through the shared flow path G between the two circumferential side flow path ribs 510 and 520 and is replenished into the As the cold air can prevent direct collision with the cold air flowing through the first cold air guide passage 310, the interference phenomenon of the cold air flow can be reduced.

In addition, in the refrigerator of the present invention, as the shared flow path G between the first circumferential side flow path rib 510 and the second circumferential side flow path rib 520 is configured to face the main cold air discharge unit 110 , the second cold air Cool air in the guide passage 320 may also be supplied to the freezing chamber 12 .

In addition, in the refrigerator of the present invention, as the sharing flow path (G) is formed by separating the lower end of the first circumferential side flow path rib 510 and the upper end of the second circumferential side flow path rib 520 apart, the shared flow path (G) The cold air passing through can smoothly flow in a specific direction according to the shape of the end of the two circumferential flow path ribs 510 and 520 .

In addition, in the refrigerator of the present invention, as the guide rib 521 is formed at the lower end of the second circumferential side flow path rib 520 , the cold air flowing to the bottom in the first cold air guide flow path 310 is the first auxiliary cold air discharge unit. (120) can be smoothly flowed.

On the other hand, the technical features related to the shared flow path (G) presented by the refrigerator of the present invention are not limited to being applied only to the grill pan assembly 1 of the form as shown in the description of the above-described embodiment and each of the drawings.

That is, in the grill pan assembly 3 for a refrigerator of a type without a changeover chamber 13 like a refrigerator according to another embodiment of the present invention shown in FIGS. 39 and 40, the shared flow path ( The structure related to G) can be applied.

The grill pan assembly 3 of another embodiment to which the shared flow path G of this embodiment is applied will be described in more detail with reference to the attached FIGS. 41 to 51 . Prior to the description, the names of each component of the refrigerator according to another embodiment of the present invention are used the same as the names of the components performing the same function of the refrigerator according to the embodiment of the present invention described above. In the case of reference numerals related to the grill pan 100 ′ and the shroud 200 ′ according to another embodiment of the are to be used separately.

41, the grill pan assembly 3 of the refrigerator according to another embodiment of the present invention includes a shroud 200', a grill pan 100', a refrigerating fan module 410, and an ice-making fan. and a module 420 .

This will be described in more detail for each configuration.

First, the shroud 200 ′ is a portion forming the rear wall of the grill pan assembly 3 .

A first inlet hole 210' and a second inlet hole 220' are formed through the shroud 200'. At this time, the first inlet hole 210' is formed in the upper central portion of the shroud 200', and the second inlet hole 220' is any one of the first inlet hole 210'. It is formed on the side (side portion where the ice-making chamber is located).

In addition, a second cold air guide passage 320' is formed in the shroud 200'. Of course, the second cold air guide flow path 320' may be formed in the grill pan 100' as in the above-described embodiment, but in another embodiment of the present invention, unlike the above-described embodiment, the second For example, the cold air guide flow path 320' is formed in the shroud 200'. At this time, the second cold air guide passage 320 ′ passes through the second inlet hole 220 ′ and the cold air introduced between the grill pan 100 ′ and the shroud 200 ′ is connected to the cold air duct 51 for the ice making room. It is a flow path (see attached FIG. 40) that guides the flow to the site.

The second cold air guide flow path 320' is formed by a plurality of flow path ribs 510', 520', and 530' protruding forward from the front surface of the shroud 200'.

In this case, each of the flow path ribs 510 ′, 520 ′, and 530 ′ is formed to protrude from the front surface of the shroud 200 ′ and form each wall surface of the second cold air guide flow path 320 ′. That is, the cold air introduced through the second inlet hole 220' is a cold air duct for an ice-making chamber along the second cold air guide passage 320' formed by each of the flow passage ribs 510', 520', 530'. 51) to the connection site.

Each of the flow path ribs 510', 520', 530' includes a first circumferential side flow path rib 510', a second circumferential side flow path rib 520' and a straight line side flow path rib 530'. do. That is, the portion in which the second inlet hole 220 ′ is formed by the three flow path ribs 510 ′, 520 ′, and 530 ′ may be partitioned from the first cold air guide passage 310 , and the second inflow hole 220 ′ is formed. The cold air passing through the ball 220' can be smoothly blown to the cold air duct 51 for the ice-making room along the second cold air guide passage 320' formed by the three passage ribs 510', 520', 530'. have.

In particular, the first circumferential side flow path rib 510 ′ and the second circumferential side flow path rib 520 ′ have a first inlet hole 210 ′ and a second inlet hole 220 ′ among the front surfaces of the shroud 200 ′. ) is formed to cross between them. That is, as the first circumferential flow path rib 510 ′ intercepts between the ice making fan module 420 and the freezing fan module 410 , the cold air provided from the freezing fan module 410 is the second cold air guide flow path. Direct discharge to the cold air outlet side of 310' is prevented.

Here, the first circumferential flow path rib 510 ′ is formed to be round to surround a portion of the upper circumference of the ice-making fan module 420 . Accordingly, the cold air radiated in the radial direction of the ice making fan 421 by the operation of the ice making fan 421 is guided by the first circumferential side flow path rib 510 ′ and smoothly toward the rotation direction of the ice making fan 421 . can be moved.

The second circumferential side flow path rib 520 ′ blocks the lower periphery of the portion where the ice-making fan module 420 is installed on the rear surface of the shroud 200 ′ from the first cold air guide flow path 310 ′ at the bottom thereof. is formed That is, the second circumferential flow path rib 520 ′ blocks the lower portion from the central portion between the ice-making fan module 420 and the freezing fan module 410 .

In addition, the second circumferential side flow path rib 520 ′ is formed to be round to surround the bottom side of the ice-making fan module 420 . Accordingly, the cold air radiated in the radial direction of the ice-making fan 421 by the operation of the ice-making fan 421 is guided by the second circumferential side flow path rib 520 ′ and flows in the rotational direction of the ice-making fan 421 . It is possible to receive guidance from the straight-side flow path rib 530'.

On the other hand, the straight-side flow path rib 530' is any of the shroud 200' from the end of the second circumferential side flow path rib 520' (the end opposite to the side where the first circumferential side flow path rib is positioned). It is formed up to one side (connection with the cold air duct for the ice-making room).

That is, the cold air flowing in the circumferential direction along the two circumferential flow path ribs 510 ′ and 520 ′ by the straight flow path rib 530 ′ can flow toward the cold air duct 51 for the ice-making chamber.

In this case, the straight-side flow path rib 530 ′ may be formed as a rib protruding from the surface of the shroud 200 ′, and as shown in the embodiment, the edge portion of the shroud 200 ′ is bent. It can also be formed by making it (recessed or protruded).

In addition, the upper end portion of the second circumferential side flow path rib 520 ′ is spaced apart from the outer surface of the lower end portion of the first circumferential side flow path rib 510 ′ so that a passage can be formed therebetween. It is formed in the form of enclosing That is, a common flow path (G') through which cold air can flow is formed by the spaced apart structure and the surrounding structure between the ends of the first circumferential side flow path rib 510 ′ and the second circumferential side flow path rib 520 ′. will be.

At this time, the shared flow path (G') serves to provide a portion of the cold air flowing through the second cold air guide flow path 310 to the first cold air guide flow path 310 to be provided to the freezing compartment 12 . .

That is, when the freezing fan 411 and the ice making fan 421 are operated at the same time, some of the cold air blown by the ice making fan 421 is additionally supplied to the freezing chamber 12, thereby rapidly controlling the temperature of the freezing chamber 12. that made this possible.

Moreover, when only the ice-making fan 421 is operated alone, the pressure on the side of the second inlet hole 220' where the ice-making fan 421 is located is relatively lower than the pressure on the side of the first inlet hole 210'. Therefore, the cold air in the freezing chamber 12 passes through the first cold air guide passage 310' and flows through the first inlet hole 210' to the portion where the second evaporator 32 is located, and then flows into the second inlet hole. There is a possibility that the phenomenon of being sucked into the second cold air guide passage 320' through 220' may occur. However, even if only the ice-making fan 421 is operated alone by providing the above-described shared flow path G′, the cold air sharing path between the first cold air guide flow path 310 ′ and the second cold air guide flow path 320 ′ is the two flow paths. As the pressure difference between the 310' and 320' is reduced, the reverse flow of the cold air from the freezing compartment 12 into the second cold air guide passage 310' is prevented.

In particular, the shared passage (G') is formed to face an upper side of the portion where the first inlet hole (210') is formed. That is, considering that the main cold air discharge part 110' of the grill fan 100' to be described later is formed on the upper side of the portion where the first inlet hole 210' is formed, the shared flow path G' is the main cold air discharge By forming to face the part 110 ′, some of the cold air flowing through the second cold air guide passage 310 ′ can be smoothly supplied to the freezing chamber 12 .

And, the straight-side flow path rib 530' is any of the shroud 200' from the end of the second circumferential side flow path rib 520' (the end opposite to the side where the first circumferential side flow path rib is positioned). It is formed up to one side (connection with the cold air duct for the ice-making room).

That is, the cold air flowing in the circumferential direction along the two circumferential flow path ribs 510' and 520' by the straight-side flow path rib 530' and the upper surface 203' of the shroud 200' is used for the ice-making chamber. It is possible to flow toward the cold air duct (51).

On the other hand, each of the above-described flow path ribs 510 ', 520 ', 530 ' is in close contact with the rear surface of the grill pan 100' to be described later, and thus is formed by each of the flow path ribs 510 ', 520', 530' The second cold air guide flow path 320 ′ becomes a closed flow path from the external environment of the grill pan assembly 3 .

Of course, although not shown, the flow path ribs 510', 520', 530' forming the second cold air guide flow path 320' are formed on the rear surface of the grill pan 100' and the shroud 200'. ) may be configured to protrude toward the front.

In addition, a plurality of guide guides 231,232 and 233 are formed on the front surface of the shroud 200'.

That is, the cold air that has passed through the first inlet hole 210 ′ through the provision of the guide guides 231,232 and 233 is the position where each auxiliary cold air discharge unit 120 ′, 130 ′, 180 ′ of the grill fan 100 ′ is formed. so that it can be supplied smoothly.

At this time, the guide guides 231,232,233 pass through the first inlet hole 210' and the cold air introduced between the grill fan 100' and the shroud 200' is the first auxiliary cold air discharge part 120'. A first guide guide 231 for guiding the flow to may be included.

At the same time, the guide guides 231,232,233 pass through the first inlet hole 210', and the cold air introduced between the grill pan 100' and the shroud 200' is the second auxiliary cold air discharge unit 130'. ) may include a second guide guide 232 to guide the flow.

At the same time, the guide guides 231,232 and 233 pass through the first inlet hole 210' and the cold air introduced between the grill pan 100' and the shroud 200' is the third auxiliary cold air discharge unit 180'. ) may include a third guide guide 233 to guide the flow.

Next, the grill pan 100' is a portion that forms the front wall of the grill pan assembly 3 for a refrigerator, and is located in front of the shroud 200'.

45, a first cold air guide passage 310' is formed in the grill pan 100'. The first cold air guide passage 310 ′ is a passage for guiding the cold air introduced between the grill pan 100 ′ and the shroud 200 ′ through the first inlet hole 210 ′ to be supplied to the freezing compartment 12 . to be.

The first cold air guide passage 310 ′ is formed by protruding (or recessing) the rear surface of the grill pan 100 ′ forward. The first cold air guide passage 310' guides the cold air to flow from one side to the other around the portion where the first seating part 160' is formed. Of course, although not shown, the first cold air guide passage 310' may be formed by recessing the front surface of the shroud 200' to the rear, and a separate rib (shown in the figure) may be formed by recessing the front surface of the shroud 200'. omitted) may be additionally formed to provide the first cold air guide flow path 310'.

In particular, in the portion opposite to the position where the first inlet hole 210' of the shroud 200' of the first cold air guide passage 310' is formed, the first seating part ( 160') is formed, and a second seating part 170' in which the ice-making fan module 420 is positioned is formed in a portion opposite to the position where the second inlet hole 220' is formed. At this time, each of the seating units 160 ′ and 170 ′ is formed as a recessed groove to accommodate a part of each fan module 410 , 420 .

Reference numerals 191, 192 and 193 in FIG. 45 attached are accommodating guides formed on the rear surface of the grill pan 100', and into the accommodating guides 191, 192, 193, the front side of each guide guide (231,232, 233) formed on the front surface of the shroud 200' The ends are accepted.

In addition, the main cold air discharge part 110' is formed in the grill pan 100'.

The main cold air discharge unit 110 ′ is an open portion for supplying cold air to the freezing compartment 12 , and is formed in an upper portion of the first seating portion 160 ′ among the grill pan 100 ′.

In particular, the main cold air discharge unit 110' is formed of a tubular body protruding forward. That is, the cold air passing through the main cold air discharge unit 110' can be given straightness, and thus the cold air passing through the main cold air discharge unit 110' does not spread up and down but is discharged straight forward to the freezing chamber. It is possible to supply cold air up to the front side (rear wall surface of the freezer door 40) inside (12).

At the same time, the main cold air discharge unit 110 ′ is formed to cross the portion where the upper end of the refrigeration fan module 410 is located. That is, the amount of cold air discharged to the main cold air discharge unit 110 ′ is increased by positioning the main cold air discharge unit 110 ′ at a portion where the cold air is blown by the refrigerating fan 411 .

In addition, auxiliary cold air discharge portions 120', 130', 180' are formed in the grill pan 100'.

These auxiliary cold air discharge units 120 ′, 130 ′, and 180 ′ are holes provided to supply cold air to an intermediate space in the freezing compartment 12 . That is, considering that the main cold air discharge unit 110 ′ is configured to supply cold air only to the upper space within the freezing compartment 12 , the intermediate space may have a relatively insufficient supply of cold air compared to the upper space. Accordingly, sufficient cold air can be supplied to the intermediate space in the freezing compartment 12 through the additional provision of the auxiliary cold air discharge units 120 ′, 130 ′, and 180 ′.

The auxiliary cold air discharge units 120 ′, 130 ′, and 180 ′ may be formed along the bottom surface of the first cold air guide passage 310 ′.

That is, while the cold air flowing along the first cold air guide passage 310' flows along the bottom surface of the first cold air guide passage 310', each of the auxiliary cold air discharge units 120', 130', 180') It is to be discharged to the freezing chamber 12 through the.

These auxiliary cold air discharge units 120', 130' and 180' are formed on either side (left side in the drawing when the grill fan is viewed from the front) in the first cold air guide flow path 310' (see attached FIG. 44). The first auxiliary cold air discharge unit 120' and the second auxiliary cold air discharge unit 130' formed on the other side (right side in the drawing when the grill pan is viewed from the front) (see attached FIG. 44) and the two A third auxiliary cold air discharge unit 180 ′ formed between the auxiliary cold air discharge units 120 ′ and 130 ′ is included.

That is, while cold air flows along the first cold air guide passage 310', the first auxiliary cold air discharge unit 120', the third auxiliary cold air discharge unit 180', and the second auxiliary cold air discharge unit 130' ) so that it can be additionally supplied to the freezing chamber 12 while passing through it sequentially.

At this time, the main cold air discharge unit 110' is formed to be larger than the combined size of each of the auxiliary cold air discharge units 120', 130', 180', so that most of the cold air blown by the refrigeration fan module 410 is It is supplied into the freezing chamber 12 through the main cold air discharge unit 110'.

In addition, the first auxiliary cold air discharge unit 120 ′ and the second auxiliary cold air discharge unit 130 ′ may be formed of a tubular body protruding forward.

That is, the cold air passing through the two auxiliary cold air discharging units 120' and 130' can be given straightness, and thus the cold air passing through the auxiliary cold air discharging units 120' and 130' does not spread up and down. It is possible to supply cold air up to the front side in the freezing compartment 12 while being discharged directly to the front.

In addition, the third auxiliary cold air discharge unit 180 ′ is formed to discharge cold air toward both side walls in the freezing compartment 12 . That is, the third auxiliary cold air discharge unit 180 ′ is formed as a tubular body with both sides open, and the cold air guided into the third auxiliary cold air discharge unit 180 ′ while flowing along the first cold air guide flow path 310 ′ is It is intended to be discharged toward both wall surfaces in the freezing chamber 12 .

In addition, the front surface of the third auxiliary cold air discharge unit 180 ′ is inclined so as to protrude forward toward both sides with respect to any one portion as a reference (inclination starting point). That is, the cold air guided into the second auxiliary cold air discharge unit 180 ′ by the inclined structure of the front can smoothly flow to both sides.

In particular, the third auxiliary cold air discharge unit 180 ′ is configured such that the amount of cold air discharged to the communication part with the ice-making chamber recovery duct 52 among the cold air discharged from both sides is formed to be greater.

That is, the cold air flowing through the ice-making chamber 21 is guided to the wall surface of either side of the freezing chamber 12 so that it is recovered through the recovery duct 52 for the ice-making chamber. The cold air temperature constitutes a relatively high temperature range compared to the cold air temperature of the other wall side.

Accordingly, the starting point of the inclination of the third auxiliary cold air discharge unit 180' is not the center of the third auxiliary cold air discharge unit 180', but one wall (the wall opposite to the wall to which the ice-making room recovery duct is connected) side. By placing it biasedly, a larger amount of cold air can be supplied to the side of the wall to which the recovery duct 52 for the ice-making room is connected. Accordingly, the temperature increase of the corresponding part due to the cold air recovered through the recovery duct 52 for the ice-making room and the temperature non-uniformity for each part of the freezing chamber are resolved.

In addition, the grill pan 100 ′ is further provided with a suction guide 140 ′ for guiding the recovery flow of the cold air flowing through the freezing compartment 12 . At this time, the suction guide 140 ′ is formed at the lower end of the grill pan 100 ′, and the cold air recovered after circulating in the freezing chamber 12 flows into the lower end of the second evaporator 32 .

In this case, the suction guide 140' is inclined at the same (or similar) angle (or round) as the wall forming the bottom of the rear side of the freezing compartment 12 toward the lower end. That is, the cold air flowing along the bottom surface of the freezing chamber 12 is guided by the suction guide 140 ′ so that it can smoothly flow to the lower end of the second evaporator 32 .

On the other hand, the cold air inflow side portion of the second cold air guide flow path 320 ′ (the peripheral side portion of the first inlet hole) is provided by being divided into a plurality of cold air inflow regions 321 ′, 322 ′, and 323 ′, respectively. .

That is, the second cold air guide flow path 320 ′ is a first circumferential flow path rib 510 ′ and a first circumferential side flow path rib 520 ′ that are commonly located between the ice making fan module 420 . The region 321 ′, the second region 322 ′ positioned between the bottom surface of the ice-making fan module 420 and the second circumferential flow path rib 520 ′, and the upper surface of the ice-making fan module 420 , Third regions 323 ′ which are positioned between the first circumferential side flow path ribs 510 ′ and communicate with the cold air outlet side portion of the second cold air guide flow path 320 ′ are provided, respectively.

Each of these regions 321 ′, 322 ′, and 323 ′ may be divided by respective fastening ribs 422a ′, 422b ′, and 422c ′ for coupling the ice-making fan module 420 . At this time, each of the fastening ribs 422a', 422b' and 422c' includes a first fastening rib 422a' positioned adjacent to the first circumferential side flow path rib 510' and a second circumferential side flow path rib 520. '), a second fastening rib 422b' positioned adjacent to ') and a third fastening rib 422c' positioned adjacent to the straight-side flow path rib 530' may be included.

That is, when viewed based on the position of the ice-making fan module 420 , the first region 321 ′ includes the first fastening rib 422a ′ and the second fastening rib ( 422a ′) and the second fastening rib ( 422b'), and the second area 322' is a region between the second fastening ribs 422b' and the third fastening ribs 422c' on the peripheral side of the ice-making fan module 420, and The third region 323 ′ is a region between the first fastening ribs 422a ′ and the third fastening ribs 422c ′ on the peripheral side of the ice making fan module 420 .

In addition, the first area 321' communicates with the shared flow path G', the second area 322' communicates with the supply flow path 204e, and the third area 323' communicates with the second cold air guide. It communicates with the cold air discharge side of the flow path 320'. In this case, the supply flow path 204e is a flow path formed to guide the supply of cold air to the bottom side of the first cold air guide flow path 310', and supplies cold air to the freezing chamber 12 when the ice-making fan 421 is operated alone to supply the first cold air. It serves to resolve the pressure difference between the inlet hole 210' and the second inlet hole 220'.

At the same time, the third region 323 ′ is configured to supply an amount of cold air approximately equal to the combined size of the first region 321 ′ and the second region 322 ′, and the second region 322 ′. ) is made to supply a relatively large amount of cold air compared to the first region 321 ′. That is, about half of the total cold air blown by the operation of the ice-making fan 421 is supplied to the ice-making chamber 21 through the third area 323', and the other half is the first area 321' and the second area. It is supplied to the first cold air guide passage 310' through the region 322'.

At this time, the cold air supplied to the first region 321 ′ is discharged toward the upper surface in the first cold air guide passage 310 ′ through the shared passage G′, and is supplied to the second region 322 ′. The cold air is discharged toward the bottom of the first cold air guide passage 310' through the supply passage 204e.

Through this differentiation of the amount of cold air supplied to each part, while the cold air is supplied to the ice making chamber 21 , sufficient cold air can also be supplied to the freezing chamber 12 .

Next, the refrigerating fan module 410 and the ice making fan module 420 are positioned between the shroud 200' and the grill pan 100'. In particular, the refrigerating fan module 410 is positioned in the first inlet hole 210', and the ice making fan module 420 is positioned in the second inlet hole 220'. The detailed structures of the refrigerating fan module 410 and the ice making fan module 420 are the same as those of the above-described embodiment.

Hereinafter, the temperature control process of each of the storage compartments 12 and 21 by the operation of the grill pan assembly 3 for a refrigerator according to another embodiment of the present invention described above will be described in more detail.

First, a process for controlling the temperature of the freezing compartment 12 will be described with reference to FIGS. 46 and 47 attached thereto.

46 is a side cross-sectional view illustrating a flow of cold air during a freezing operation in a freezer compartment of a refrigerator to which a grill pan assembly for a refrigerator is applied according to another embodiment of the present invention, and FIG. 47 is a grill pan assembly for a refrigerator of FIG. 46 It is an enlarged view of the main part shown to explain the flow of cold air in the first cold air guide flow path during the refrigeration operation by

As shown, the temperature control of the freezing chamber 12 is performed by the operation of the freezing fan module 410 and the compressor (not shown). That is, the operation for controlling the temperature of the freezing chamber 12 is performed by the rotation of the refrigerating fan 411 by the supply of power to the refrigerating fan module 410 and the heat exchange operation of the second evaporator 32 by the operation of the compressor. .

And, when the freezing fan 411 of the freezing fan module 410 is operated, the air in the freezing compartment 12 flows through the second evaporator 32 by the air blowing force by the freezing fan 411, It is heat-exchanged while passing through the second evaporator 32 .

In addition, the heat-exchanged air (cold air) passes through the first inlet hole 210' of the shroud 200' and flows into the first cold air guide passage 310' and then the first cold air guide passage 310'. ) flows along me.

The cold air flowing along the first cold air guide passage 310 ′ in this way includes the main cold air discharge unit 110 ′, the first auxiliary cold air discharge unit 120 ′ and the third auxiliary formed in the first cold air guide passage 310 ′. The cold air is supplied into the freezing compartment 12 while sequentially passing through the cooling air discharge unit 180 ′ and the second auxiliary cooling air discharge unit 130 ′.

At this time, about half or more of the cold air passing through the first inlet hole 210 ′ is discharged to the upper space of the freezing chamber 12 through the main cold air discharge unit 110 ′, and the remaining cold air is discharged through the first auxiliary cold air discharge unit 110 ′. The portion 120', the third auxiliary cold air discharge unit 180', and the second auxiliary cold air discharge unit 130' are discharged to the space in the middle of the freezing compartment 12.

Of course, the cold air that has not been discharged into the intermediate space in the freezing compartment 12 through the respective auxiliary cold air discharge units 120', 130' and 180' is circulated again to the place where the main cold air discharge unit 110' is located. do.

In particular, since the bottom surface in the first cold air guide passage 310 ′ is formed to be round, the cold air passing through the first auxiliary cold air discharge unit 120 ′ runs along the bottom surface of the first cold air guide passage 310 ′. During the flow, it may smoothly flow to the third auxiliary cold air discharge unit 180 ′ and the second auxiliary cold air discharge unit 130 ′.

Accordingly, in the freezing chamber 12 , cold air is evenly supplied to both the upper space, the middle space, and both spaces.

In addition, the cold air supplied into the freezing chamber 12 through each of the cold air discharge units 110', 120', 130', and 180' flows in the freezing chamber 12 and is then suction formed in the grill fan 100'. It is recovered to the air inlet side of the second evaporator 32 under the guidance of the guide 140'.

In particular, considering that the suction guide 140 ′ is formed to be inclined (or round) of the freezing chamber 12 , the cold flowing along the inclined wall of the machine room 15 after flowing through the freezing chamber 12 is the suction. It may be guided by the guide 140 ′ to smoothly flow to the air inlet side of the second evaporator 32 .

And, while the freezing operation of supplying cold air to the freezing chamber 12 is performed, the temperature in the freezing chamber 12 is continuously checked by the temperature sensor 150' installed in the grill fan 100', and through this, the freezing chamber When it is confirmed that the temperature in (12) is lower than the set temperature (if the set temperature condition is satisfied), the operation of the refrigerating fan 411 and the refrigerating cycle is stopped and the cold air supply is stopped.

Of course, if the temperature in the freezing compartment 12 is higher than the set temperature, the cooling fan 411 and the refrigerating cycle are operated again to supply cold air into the freezing compartment 12 .

Accordingly, the temperature in the freezing chamber 12 is controlled by the repeated circulation operation of the above-described air (cold air).

Meanwhile, the ice making fan 421 may also be operated while the temperature control of the above-described freezing compartment 12 is being performed.

That is, considering that the ice-making operation is always performed except under special conditions (eg, when the ice-making chamber is full of ice, etc.), the continuous ice-making operation may be performed even while the freezing operation is being performed.

If the ice making operation is also performed while the freezing operation is being performed, the flow of cold air sequentially passing through the second inlet hole 220 ′ and the second cold air guide passage 320 ′ is generated by the operation of the ice making fan 421 . do.

A portion of the cold air generated by the operation of the ice-making fan 421 is supplied to the first cold air guide passage 310' through the shared passage G', and the rest is supplied to the second cold air guide passage 320'. It is supplied to the ice-making chamber 21 through the connected cold air duct 51 for the ice-making chamber.

That is, the cold air blown through the second inlet hole 220' to the first area 321' of the second cold air guide passage 320' passes through the shared passage G' and passes through the first cold air guide passage ( 310'), the cold air that is blown into the second area 322' of the second cold air guide passage 320' through the second inlet hole 220' passes through the supply passage 204e to the first The cold air supplied to the cold air guide flow path 310' and blown through the second inlet hole 220' to the third area 323' of the second cold air guide flow path 320' is the second cold air guide flow path ( The cold air is supplied to the ice-making chamber 21 through the cold air duct 51 for the ice-making chamber connected to the discharge side of the cold air 320'. This is as shown in the attached Figure 48.

As a result, not only the cold air blown by the operation of the freezing fan 411 but also a part of the cold air blown by the operation of the ice-making fan 421 are supplied into the freezing chamber 12, so that only the freezing fan 411 operates alone. A greater amount of cold air can be supplied than when

In particular, the cold air flowing through the ice-making chamber 21 is recovered to the freezing chamber 12 through the recovery duct 52 for the ice-making chamber.

At this time, the cold air recovered to the freezing chamber 12 through the ice-making chamber recovery duct 52 is higher than the temperature of the cold air existing in the freezing chamber 12 . Accordingly, in the freezing chamber 12 , a phenomenon occurs in that the cold air temperature of one side wall portion to which the ice-making chamber recovery duct 52 is connected and the opposite side wall portion are different from each other.

However, the cold air supplied to the freezing chamber 12 through the third auxiliary cold air discharge unit 180 ′ while flowing through the first cold air guide passage 310 ′ is the inclined front surface of the third auxiliary cold air discharge unit 180 ′. It is supplied to the freezing chamber 12 by receiving the guidance of the flow direction by the , and in particular, the third auxiliary cold air discharge unit 180 ′ is further directed toward the wall surface of the freezing chamber 12 connected to the ice-making chamber recovery duct 52 . Considering that a lot of cold air is supplied, the temperature difference between the side walls of the freezing compartment 12 is reduced.

Accordingly, temperature control of the freezing compartment 12 can be performed more accurately.

Next, an operation (ice-making operation) for controlling the temperature of the ice-making chamber 21 will be described with reference to FIGS. 49 to 51 .

49 is a side cross-sectional view illustrating a flow of cold air during an ice-making operation in an ice-making chamber of a refrigerator to which a grill fan assembly for a refrigerator is applied according to another embodiment of the present invention, and FIG. 50 is a grill pan for the refrigerator of FIG. It is an enlarged view showing the main part to explain the flow of cold air by the assembly, and FIG. 51 is an enlarged view of the main part of the refrigerator to which the grill fan assembly for a refrigerator according to another embodiment of the present invention is applied. It is an enlarged view of the main part shown for this purpose.

As shown, the temperature control of the ice-making chamber 21 is performed by the operation of the ice-making fan 421 by supplying power to the ice-making fan module 420 . At this time, the compressor may be operated or stopped according to the operating conditions of the freezing compartment 12 .

When the ice-making fan 421 is operated, the air existing in the freezing compartment 12 passes through the second evaporator 32 by the air blowing force by the ice-making fan 421 and then through the second inlet hole of the shroud 200'. It passes through 220 ′ and flows into the first region 321 ′, the second region 322 ′, and the third region 323 ′ of the second cold air guide passage 320 ′, and continues to each region. (321', 322', 323') is discharged from the second cold air guide passage 320' through the communication portion.

At this time, the cold air introduced into the first region 321 ′ by the operation of the ice-making fan 421 passes through the shared passage G′ and is supplied to the upper surface of the first cold air guide passage 310 ′, and the second The cold air blown to the area 322' is supplied to the bottom side in the first cold air guide passage 310' through the supply passage 204e, and the cold air blown to the third area 323' is a cold air duct 51 for an ice-making room. ) is supplied to the ice making chamber 21 .

At the same time, the cold air supplied to the first cold air guide passage 310' through the shared passage G' is blown toward the main cold air discharge unit 110' in the first cold air guide passage 310'. The cold air supplied to the freezing chamber 12 through the main cold air discharge unit 110', and supplied to the first cold air guide passage 310' through the supply passage 204e, is a first cold air guide passage 310'. ) while flowing along the bottom surface, it is supplied to the freezing compartment 12 through the first auxiliary cold air discharge unit 120 ′, the third auxiliary cold air discharge unit 180 ′, and the second auxiliary cold air discharge unit 130 ′.

In particular, the third region, which is an upper portion of the ice-making fan 421, among the cold air that passes through the second inlet hole 220' and is supplied into the second cold air guide passage 320' by the blowing force of the ice-making fan 421 ( 323') and then flows to the cold air discharge side along the second cold air guide passage 320'. At this time, since the cold air flows along a sufficient distance from the third area 323' to the cold air discharge side, it is possible to reduce the flow resistance generated by the third area 323' and the cold air discharge side being adjacent to each other.

Accordingly, the inside of the freezing chamber 12 is substantially similar to that of the ice-making chamber 21 by the cold air supplied from the second cold air guide passage 320' through the shared passage G' and the supply passage 204e. will keep That is, since the pressures of the freezing compartment 12 and the ice-making compartment 21 are approximately balanced, even if only the ice-making fan 421 is operated for the ice-making operation, the cold air in the freezing compartment 12 may It can be prevented (or minimized) from passing through the first inlet hole 210 ′ in the reverse direction and flowing into the second inlet hole 220 ′ and the second cold air guide passage 320 ′.

In addition, since the cold air outlet side of the supply passage 204e is configured to spray toward one end of the bottom surface of the first cold air guide passage 310', it passes through the supply passage 204e and the first cold air guide passage 310'. ), the cold air injected into it flows along the bottom surface of the first cold air guide passage 310 ′. In this process, the cold air sequentially passes through the first auxiliary cold air discharge port 120', the third auxiliary cold air discharge port 180', and the second auxiliary cold air discharge port 130' on the first cold air guide flow path 310'. While being supplied into the freezing chamber (12).

Accordingly, the freezing chamber 12 has a sufficient pressure, so that the reverse flow of cold air from the freezing chamber 12 to the second cold air guide passage 320' is prevented.

On the other hand, the cold air discharged to the third region 323 ′ flows toward the second region 322 ′ located on the rotational direction side of the ice-making fan 421 , but the third region 323 ′ and the second region 323 ′ and Considering that the second area 322' is substantially partitioned from each other by the ice-making fan module 420, all of the cold air discharged to the third area 323' is guided by the second cold air guide passage 320'. It flows toward the cold air discharge side of the second cold air guide passage 320 ′.

Accordingly, although the amount of cold air supplied to the ice-making chamber 21 is smaller than that of the cold air supplied to the freezing chamber 12, it can be smoothly pumped to the ice-making chamber 21 by the high blowing pressure.

In addition, the cold air supplied to the ice making chamber 21 freezes water (or other beverages) existing in the ice tray (not shown) while flowing in the ice making chamber 21 .

Then, the cold air flowing in the ice-making chamber 21 flows to the ice-making chamber recovery duct 52 , and is subsequently recovered into the freezing chamber 12 under the guidance of the ice-making chamber recovery duct 52 .

Thereafter, the cold air recovered to the freezing chamber 12 flows in the freezing chamber 12 and is guided by the suction guide 140 ′ formed in the grill fan 100 ′ to the air inlet side of the second evaporator 32 . is recovered

If the temperature in the ice-making chamber 21 is lower than the set temperature, the operation of the ice-making fan 421 is stopped and the supply of cold air to the ice-making chamber 21 is stopped.

Accordingly, the temperature in the ice-making chamber 21 is controlled by the repeated circulating operation of the above-described air (cold air).

Of course, the cold air introduced into each region of the second cold air guide passage 320 ′ during the ice making operation may flow to other regions by rotational flow according to the operation of the ice making fan 421 .

However, since the respective regions 321 ′, 322 ′, and 323 ′ are substantially partitioned from each other due to the portions where the respective fastening ribs 422a ′, 422b ′, and 422c ′ of the ice making fan module 420 are installed. The flow of cold air between the regions 321 ′, 322 ′, and 323 ′ is only minimal and does not significantly affect the flow of cold air flowing through other regions.

As such, the shared flow passages (G, G') of the grill pan assembly provided in the refrigerator of the present invention include the freezing fan 411 and the ice-making fan 421 as shown in the one and other embodiments of the present invention described above. In a structure in which the installed first inlet holes 210 and 210' and the second inlet holes 220 and 220' are positioned adjacently, and the first cold air guide passages 310 and 310' and the second cold air guide passages 320 and 320' are formed adjacent to each other. When the freezing fan 411 and the ice making fan 421 are simultaneously operated, the effect of further increasing the amount of cold air supplied to the freezing chamber 12 is provided.

Claims (20)

a cabinet having an upper refrigerator compartment and a lower freezer compartment;
a refrigerating compartment door opening and closing the refrigerating compartment of the cabinet and having an ice making compartment;
a grill fan assembly provided in the freezer compartment of the cabinet and having an ice-making fan module for supplying cold air to the ice-making chamber and a freezing fan module for supplying cold air to the freezing chamber; and
The grill pan assembly is
A shroud having a first inlet hole and a second inlet hole formed therein, and a grill fan having a cold air outlet formed thereon so as to discharge cold air into the freezer while being coupled to the front surface of the shroud,
At least one surface of the opposing surfaces between the shroud and the grill fan guides a first cold air guide passage for guiding the flow of cold air introduced through the first inlet hole, and a first cold air guide passage for guiding the flow of cold air introduced through the second inlet hole. A second cold air guide flow path is formed,
and the first cold air guide passage and the second cold air guide passage are configured to share the cold air of each cold air guide passage by a shared passage. The method of claim 1,
The first inlet hole is formed to be located closer to the upper surface of the first cold air guide passage than the lower surface in the first cold air guide passage among the central portion of the shroud,
The second inlet hole is a refrigerator, characterized in that formed on one side of the first inlet hole. 3. The method of claim 2,
The first cold air guide flow path is formed to be rounded around a portion of the rear surface of the grill pan where the freezing fan module is located, with an end reaching the top surface of the grill pan opposite to the ice making pan,
The refrigerator, characterized in that the end of the first cold air guide passage is formed to be opened to the upper portion of the grill pan. 3. The method of claim 2,
The second cold air guide flow path is formed from between the freezing fan module and the ice-making fan module on the rear surface of the grill fan to surround the perimeter of the ice-making fan module and the end to the side surface of the grill pan,
The refrigerator, characterized in that the end of the second cold air guide passage is formed to be opened to the side of the grill pan. The method of claim 1,
a first flow path rib that protrudes downward from the upper end of the rear surface of the grill pan and is formed to block a portion between the ice-making fan module and the freezing fan module;
and a second flow path rib that protrudes upward from the lower end of the rear surface of the grill pan and is formed to block the remaining portion between the ice-making fan module and the freezing fan module. 6. The method of claim 5,
A lower portion of the first passage rib and a portion of an upper portion of the second passage rib are positioned to face each other while crossing each other;
The shared flow path is formed at an intersection of the first flow path rib and the second flow path rib. 7. The method of claim 6,
and the shared flow path is formed by separating a lower end of the first flow path rib and an upper end of the second flow path rib apart from each other. 6. The method of claim 5,
The refrigerator, characterized in that the first flow rib is formed in a round structure surrounding the periphery of the portion where the ice making fan module is installed. 6. The method of claim 5,
and the second flow path rib is formed in a round structure that surrounds a periphery of a portion where the ice-making fan module is installed. 6. The method of claim 5,
The lower end of the first flow path rib is formed to reach a lower position than the central position of the ice-making fan module. 6. The method of claim 5,
and the upper end of the second flow path rib is formed to reach a higher position than the central position of the ice-making fan module. 6. The method of claim 5,
and a lower end of the first flow path rib is disposed relatively closer to the Zepping fan module than an upper end of the second flow path rib. 6. The method of claim 5,
The refrigerator according to claim 1, wherein the cold air discharge unit includes a main cold air discharge unit for guiding the cooling air to be discharged to a space where the upper wall of the freezer is located. 14. The method of claim 13,
The refrigerator, characterized in that the main cold air discharge portion is formed to be positioned further above the center of the freezing fan module. 15. The method of claim 14,
The upper and lower heights of the main cold air discharge part are formed to have a shorter height than the upper and lower heights of the refrigeration fan module,
The left and right lengths of the main cold air discharge part are formed to be longer than the left and right widths of the refrigeration fan module. 16. The method of claim 15,
The refrigerator, characterized in that the shared flow path is formed to face one end of the main cold air discharge part. 6. The method of claim 5,
The refrigeration fan module is configured to include a refrigeration fan and a first installation frame for installing the refrigeration fan to the grill pan,
The first installation frame is a refrigerator, characterized in that fastened to the grill pan by a plurality of fastening ribs. 18. The method of claim 17
The refrigerator, characterized in that at least one of the respective fastening ribs is positioned to block the direct flow of the cold air blown by the rotation of the freezing fan toward the common flow path. 6. The method of claim 5,
and a guide rib guiding cold air to flow to one end of a bottom surface of the first cold air guide passage is formed at a lower end portion of the second flow path rib. 20. The method of claim 19,
and an auxiliary cold air discharge unit guided by the guide rib to discharge the cold air flowing along a bottom surface of the first cold air guide passage to the freezing chamber.

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