KR20210072575A - grille-fan assembly for refrigerator - Google Patents

Abstract

The present invention is to provide a new type of refrigerator grille fan assembly capable of accurate temperature control of a storage compartment. More particularly, the present invention is made such that a temperature sensor for sensing the temperature of a freezing compartment is installed in a grille fan, and the temperature sensor is insulated from the rear side as an insulation part, and, in particularly, and suggests that the insulation part is integrally formed with a damper cover for insulating a flow path opening and closing module and installed so as to insulate the temperature sensor when the flow path opening and closing module is installed, and this prevents the temperature sensor from erroneously sensing the temperature in the freezing compartment due to the influence of an evaporator or an accumulator instead of the freezing compartment.

Description

Grill pan assembly for refrigerator {grille-fan assembly for refrigerator}

The present invention relates to a grill pan assembly of a refrigerator having a refrigerating compartment, a freezing compartment, and a switching compartment each providing a storage space.

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.

In addition, a grill pan assembly is provided at the rear of each storage chamber, which is a rear wall surface of the cabinet, and is divided into a front storage chamber and a rear evaporator based on the grill pan assembly.

In addition, a fan module is installed in the grill fan assembly, and the air in the cabinet is operated to be supplied to the storage chamber after heat exchange through the evaporator.

The fan module and the evaporator are operated based on the temperature of the storage compartment (freezing compartment or refrigerating compartment) sensed by the temperature sensor to control the temperature in the storage compartment.

The above-described temperature sensor is installed on the floor, ceiling, or side wall surface of the storage room as shown in Korean Patent Application Laid-Open No. 1999-0031033, Korean Patent Application Laid-Open No. 10-2008-0014407, and Korean Patent Application Laid-Open No. 10-2010-0097928. Alternatively, as shown in Patent Registration No. 10-1852677, it is installed in the grill pan assembly and configured to sense the temperature of the corresponding storage room.

However, in the case of a structure in which a temperature sensor is installed on one wall of a storage room among the above-described conventional techniques, there is an inconvenience of wiring due to the need to connect a power line to the corresponding part.

That is, since electrical wiring for only the temperature sensor has to be made, there is a problem in that it is not only inconvenient to install, but also takes a long time to work.

Of course, since the electric wiring for the fan module is formed in the grill pan assembly, the difficulty of electric wiring for the temperature sensor installed in the grill pan assembly can be solved.

However, considering that the evaporator is located at the rear of the grill pan assembly, the temperature sensor is affected by the evaporator, and accordingly, there is a risk that an error in temperature sensing may occur.

That is, even though the internal temperature of the storage compartment has not reached the set temperature, the temperature sensor determines that the internal temperature of the storage compartment is lower than the actual temperature, so that the temperature control of the storage compartment cannot be accurately performed.

Accordingly, in the prior art, efforts have been made to design the evaporator to be positioned lower than the grill pan assembly and to design the temperature sensor to be positioned higher than the evaporator. However, even in this case, it is difficult to solve the sensing error because the temperature sensor is not only affected by the evaporator but also received the influence of the accumulator connected to the evaporator.

In addition, a power line is drawn out from the temperature sensor, and there is a risk that the power line may be bent during assembly because a structure for fixing the power line in a fixed position is not provided in the prior art, and the power line cannot be maintained in the correct position. There was a fear that the power line was short-circuited from the temperature sensor due to the flow phenomenon.

On the other hand, when one evaporator is used to control the temperature of the two storage compartments, a flow path for guiding the flow of cold air into each storage compartment is formed in the grill fan assembly, and the flow path must be configured to selectively open and close.

However, since the above-described grill pan assembly is located adjacent to the evaporator, there is a fear that the device provided for opening and closing the flow path is frozen due to the low temperature of the evaporator.

Unexamined Patent Publication No. 1999-0031033 Laid-Open Patent Publication No. 10-2008-0014407 Unexamined Patent Publication No. 10-2010-0097928 Registered Patent No. 10-1852677

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 prevent the temperature of the accumulator from being affected by the temperature of the accumulator when the temperature sensor is installed in the grill pan assembly, so that accurate temperature control of the storage room is possible It is to provide a possible new type of grill pan assembly for refrigerators.

Another object of the present invention is to provide a new type of grill pan assembly for a refrigerator, which allows the installation of a temperature sensor to be stably performed on the grill pan assembly and a simplified structure for installing the temperature sensor.

Another object of the present invention is to provide a new type of grill fan assembly for a refrigerator capable of preventing a short circuit from a temperature sensor by allowing a power line connected to a temperature sensor to be maintained in a fixed position.

Another object of the present invention is to provide a new type of grill pan assembly for a refrigerator capable of preventing a possibility that a flow path opening/closing module provided in the grill pan assembly may freeze under the influence of an evaporator.

In order to achieve the above object, the grill pan assembly for a refrigerator of the present invention proposes that a temperature sensor for sensing the temperature of the freezing compartment is installed in the grill pan, and the temperature sensor is insulated from the rear side by an insulating part, thereby This is to prevent the temperature sensor from erroneously detecting the temperature in the freezer due to the influence of the temperature in other parts than the freezer.

In addition, the grill fan assembly for refrigerator of the present invention proposes that the heat insulating part is installed to block the temperature sensor from the evaporator or the accumulator connected to the evaporator, whereby the low-temperature cold air emitted from the evaporator or the accumulator affects the temperature sensor. This was done to prevent it from happening.

In addition, the grill pan assembly for a refrigerator according to the present invention proposes that the mounting part on which the temperature sensor is mounted is formed to protrude from the front of the grill pan, so that the temperature sensor accurately measures the temperature in the freezer compartment.

In addition, the grill pan assembly for refrigerator of the present invention proposes that a mounting groove is formed in a recessed portion on the rear surface of the mounting part, and the temperature sensor is inserted and mounted in the mounting groove, thereby enabling the temperature sensor to be easily installed.

In addition, the grill pan assembly for a refrigerator according to the present invention proposes that a gripping end for gripping the temperature sensor is formed in the mounting groove, thereby maintaining the stable mounting state of the temperature sensor.

In addition, the grill pan assembly for refrigerator of the present invention suggests that the gripping end is formed to protrude inwardly from at least one wall surface in the mounting groove, so that both sides of the temperature sensor are gripped.

In addition, the grill pan assembly for a refrigerator according to the present invention proposes that an exposure hole is formed in the mounting portion, thereby exposing the temperature sensor in the mounting groove to the storage compartment.

In addition, the grill pan assembly for a refrigerator of the present invention suggests that two or more exposed holes are formed in plurality, thereby allowing the temperature sensor to accurately sense the temperature in the freezer compartment.

In addition, the grill pan assembly for a refrigerator of the present invention suggests that the front exposure hole is formed through the front surface of the mounting part, thereby allowing the temperature sensor to accurately sense the temperature of the freezer compartment.

In addition, the grill fan assembly for a refrigerator of the present invention proposes that side exposure holes are formed through both sides of the mounting part, so that the temperature sensor accurately senses the temperature of cold air flowing in the freezer compartment.

In addition, the grill pan assembly for a refrigerator of the present invention proposes that a wire receiving groove is formed in the mounting portion, thereby preventing the power line of the temperature sensor from flowing or short-circuited.

In addition, the grill pan assembly for refrigerator of the present invention suggests that the wire receiving groove is formed from the bottom of the mounting groove to the side of the grill pan, so that the power line of the temperature sensor is stably connected without being short-circuited from the temperature sensor. will be.

In addition, the grill pan assembly for a refrigerator of the present invention suggests that a mounting end at which the flow path opening/closing module is mounted is formed in the cold air guide flow path, thereby reducing the overall size of the grill pan assembly by allowing the flow path opening/closing module to be installed on the grill pan. it was made to be

In addition, the grill pan assembly for refrigerator of the present invention suggests that the mounting part is formed on the side of the mounting end, whereby the temperature sensor mounted on the mounting part is positioned side by side with the flow path opening/closing module and spaced apart from the evaporator as much as possible.

In addition, the grill fan assembly for a refrigerator according to the present invention is provided with a damper cover for enclosing the flow path opening/closing module, thereby preventing the flow path opening/closing module from freezing due to the influence of cold air or the influence of the evaporator.

In addition, the grill pan assembly for a refrigerator of the present invention suggests that the heat insulating part is integrally formed with the damper cover, thereby eliminating the inconvenience of assembling the heat insulating part separately.

In addition, the grill pan assembly for refrigerator of the present invention suggests that the heat insulating part is formed to protrude from the side surface of the damper cover, so that the heat insulating part covers the temperature sensor by installing the damper cover.

In addition, the grill pan assembly for a refrigerator according to the present invention suggests that the support end is formed on the front surface of the shroud, so that the heat insulating portion accurately covers the temperature sensor by assembling the shroud to the grill pan.

In addition, the grill fan assembly for a refrigerator of the present invention suggests that the damper cover and the heat insulating part are formed of an insulating material, thereby preventing the flow path opening/closing module and the temperature sensor from malfunctioning due to the influence of the evaporator or the accumulator.

In addition, the grill pan assembly for a refrigerator according to the present invention proposes that a receiving groove is formed on the rear surface of the grill pan, thereby preventing the heat insulating part from flowing when assembling the grill pan and the shroud.

In addition, the grill pan assembly for a refrigerator of the present invention suggests that a heat shield plate is provided on the front surface of the evaporator, thereby preventing the low-temperature cold air emitted from the evaporator from being conducted to the shroud.

As described above, in the grill pan assembly for a refrigerator of the present invention, the temperature sensing defect due to the influence of the evaporator and the accumulator is prevented by providing the heat insulating part covering the temperature sensor, thereby enabling accurate temperature control of the freezer compartment. .

In particular, the grill pan assembly for a refrigerator according to the present invention can be easily manufactured because the heat insulating part is integrally formed with the damper cover, and the assembly operation can be easily performed.

In addition, the grill pan assembly for a refrigerator of the present invention has an effect that the sensing reliability by the temperature sensor can be improved as the heat insulating part is configured to maintain airtightness while being in close contact with the heat insulating part accommodating groove.

In addition, the grill fan assembly for a refrigerator of the present invention has the effect of preventing the power line from being short-circuited from the temperature sensor because the power line connected to the temperature sensor can always be placed in the correct position.

In addition, the grill pan assembly for a refrigerator of the present invention has an effect that, since a heat shield is provided between the evaporator and the grill pan assembly, freezing of the flow path opening/closing module is prevented and the sensing reliability of the temperature sensor can be improved.

1 is a perspective view illustrating an external structure of a refrigerator to which a grill pan assembly for a refrigerator according to an embodiment of the present invention is applied;
2 is a perspective view schematically illustrating an internal structure of a refrigerator to which a grill pan assembly for a refrigerator according to an embodiment of the present invention is applied;
3 is a front cross-sectional view schematically illustrating an internal structure of a refrigerator to which a grill pan assembly for a refrigerator according to an embodiment of the present invention is applied;
4 is a side cross-sectional view schematically illustrating an internal structure of a refrigerator to which a grill pan assembly for a refrigerator according to an embodiment of the present invention is applied;
5 is an enlarged view of part “A” of FIG. 4
6 is an enlarged view showing the main part to explain the application state of a structure for supplying or recovering cold air to an ice-making chamber of a refrigerator to which a grill pan assembly for a refrigerator is applied according to an embodiment of the present invention;
7 is an exploded perspective view illustrating a grill pan assembly for a refrigerator according to an embodiment of the present invention;
8 is an enlarged view of part “B” of FIG. 7 to explain an installation structure for a temperature sensor of a grill pan assembly for a refrigerator according to an embodiment of the present invention; FIG.
9 is a perspective view illustrating a relationship for cold air transfer between a grill pan assembly for a refrigerator and an ice-making chamber according to an embodiment of the present invention;
10 is a front view illustrating a connection state of a grill pan assembly for a refrigerator and a cold air duct for a change-over room and a return duct for a change-over room according to an embodiment of the present invention;
11 is a rear view illustrating a connection state between the grill pan assembly for 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;
12 is a front view illustrating a grill pan in a grill pan assembly for a refrigerator according to an embodiment of the present invention;
13 is an enlarged view of part “C” of FIG. 12
14 is a rear view illustrating a grill pan in a grill pan assembly for a refrigerator according to an embodiment of the present invention;
15 is an enlarged view of part “D” of FIG. 14
16 is an enlarged view of the main part shown to explain a state in which a temperature sensor is installed in a mounting part of a grill pan among a grill pan assembly for a refrigerator according to an embodiment of the present invention;
17 is an enlarged view of a main part shown to explain a partition rib of a grill pan assembly for a refrigerator according to an embodiment of the present invention;
18 is a rear view with a shroud omitted to explain a positional relationship between each fan module and a second evaporator of the grill fan assembly for a refrigerator according to an embodiment of the present invention;
19 is a perspective view illustrating an open state of a switching damper part of a grill pan assembly for a refrigerator according to an embodiment of the present invention;
20 is a perspective view illustrating a closed state of a switching damper of a grill pan assembly for a refrigerator according to an embodiment of the present invention;
21 is a cross-sectional view showing a state viewed from the front in order to explain an open state of the switching damper of the grill pan assembly for a refrigerator according to an embodiment of the present invention;
22 is a cross-sectional view illustrating a state in which the switching damper of the grill pan assembly for a refrigerator is closed according to an embodiment of the present invention, as viewed from the front;
23 is a front view illustrating a shroud of a grill pan assembly for a refrigerator according to an embodiment of the present invention;
24 is a rear view illustrating a shroud of a grill pan assembly for a refrigerator according to an embodiment of the present invention;
25 is a front view illustrating a fan module of a grill pan assembly for a refrigerator according to an embodiment of the present invention;
26 is a rear view illustrating a fan module of a grill pan assembly for a refrigerator according to an embodiment of the present invention;
27 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 according to an embodiment of the present invention is applied;
28 is a state diagram showing 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 to which the grill pan assembly for the refrigerator according to the embodiment of the present invention is applied.
29 is an enlarged view of main parts showing a flow of cold air by each compartment rib during a freezing operation of a freezer compartment of a refrigerator to which a grill pan assembly for a refrigerator according to an embodiment of the present invention is applied;
30 is an enlarged view of main parts showing a flow of cool air by a flow path opening/closing module during a refrigeration operation of a freezer compartment of a refrigerator to which a grill fan assembly for a refrigerator according to an embodiment of the present invention is applied;
31 is a state diagram illustrating a flow of cold air by each compartment rib when a freezing operation and an ice-making operation of a refrigerator to which the grill pan assembly for a refrigerator is applied according to an embodiment of the present invention are simultaneously performed;
32 is an enlarged view of main parts showing the flow of cool air by each compartment rib when the freezing operation and the ice making operation of the refrigerator to which the grill pan assembly for a refrigerator is applied according to an embodiment of the present invention are simultaneously performed;
33 is a side cross-sectional view illustrating a flow of cold air during a refrigeration operation in a switching room of a refrigerator to which a grill pan assembly for a refrigerator according to an embodiment of the present invention is applied;
34 is an enlarged view illustrating the main part of a refrigerator to which the grill pan assembly for a refrigerator is applied according to an embodiment of the present invention;
35 is a state diagram illustrating a flow of cold air during a refrigeration operation in a switching room of a refrigerator to which a grill pan assembly for a refrigerator according to an embodiment of the present invention is applied;
36 is an enlarged view illustrating the main part of a cooling air flow by a flow path opening/closing module during a refrigeration operation in a switching room of a refrigerator to which a grill fan assembly for a refrigerator according to an embodiment of the present invention is applied;
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 to which a grill fan assembly for a refrigerator according to an embodiment of the present invention is applied;
38 is a state diagram 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 according to an embodiment of the present invention is applied;
39 is an enlarged view illustrating the main part of the refrigerator to which the grill fan assembly for refrigerator according to the embodiment of the present invention is applied to explain the flow of cool air by each compartment rib during an ice-making operation in the ice-making chamber of the refrigerator;
40 is a state diagram illustrating the flow of supply and recovery of cold air to the ice-making chamber during an ice-making operation for the ice-making chamber of the refrigerator to which the grill fan assembly for the refrigerator according to the embodiment of the present invention is applied.

Hereinafter, a grill pan assembly for a refrigerator according to a preferred embodiment of the present invention will be described with reference to the accompanying FIGS. 1 to 40 .

1 is a perspective view illustrating an external structure of a refrigerator to which a grill pan assembly for a refrigerator is applied according to an embodiment of the present invention, and FIG. 2 is a refrigerator to which a grill pan assembly for a refrigerator according to an embodiment of the present invention is applied. It is a perspective view schematically shown to explain the internal structure. 3 is a front sectional view schematically illustrating the internal structure of a refrigerator to which the grill pan assembly for a refrigerator according to an embodiment of the present invention is applied, and FIG. 4 is a grill pan assembly for a refrigerator according to an embodiment of the present invention. It is a side cross-sectional view schematically shown to explain the internal structure of the refrigerator to which is applied.

As shown in these drawings, the grill pan assembly 1 for a refrigerator according to an embodiment of the present invention has a freezer compartment (1) of a refrigerator having a refrigerating compartment (11), a freezing compartment (12), a switching compartment (13), and an ice-making compartment (21). 12) as an example.

In particular, the grill fan assembly 1 for a refrigerator according to an embodiment of the present invention has two fan modules 410 and 420 and heat-exchanged cold air passing through one of the evaporators 32 to the freezing chamber 12 and the switching chamber 13 . ) and the ice making chamber 21 is characterized in that it is configured to be selectively supplied.

Prior to the description of the embodiment, the refrigerator to which the grill pan assembly 1 for a refrigerator according to an embodiment of the present invention is applied, as shown in the accompanying FIGS. 1 to 4 , largely includes a refrigerating compartment 11 , a freezing compartment 12 , and a switching compartment. It comprises a cabinet (10) having a (13) and a door (20) for a refrigerating chamber having an ice-making chamber (21).

In this case, the refrigerating compartment 11 is a storage compartment provided to refrigerate stored items, the freezing compartment 12 is a storage compartment provided to freeze and store stored items, and the switching compartment 13 is a storage compartment provided to store stored items in a refrigerator according to the user's needs. It is a storage room provided to change and use for refrigeration or freezing storage.

At the same time, the first evaporator 31 is provided on the rear side of the refrigerating compartment 11 among the rear wall surfaces of the cabinet 10 , and the second evaporator 32 is provided on the rear side of the freezing compartment 12 among the rear wall surfaces of the cabinet 10 . 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 in an upper space in the cabinet 10 , the freezing compartment 12 is provided in a lower space in the cabinet 10 , and the switching compartment 13 is provided in the refrigerating compartment 11 . and the interlayer space in the cabinet 10 between the freezer compartment 12 and the freezer compartment 12 . Each of these storage compartments (refrigeration compartment, freezing compartment, and switching compartment) 11 , 12 , 13 is formed while being partitioned from each other by a plurality of partition walls 14 dividing the space in the cabinet 10 up and down.

In addition, the door 20 for the refrigerating compartment is a door that opens and closes the refrigerating compartment 11 and is a rotary door.

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 door 20 for the refrigerating compartment.

The ice-making chamber 21 is configured to guide supply and discharge of cold air while a guide duct 22 is connected. At this time, the guide duct 22 is made to coincide with the cold air duct 51 for the ice-making chamber and the recovery duct 52 for the ice-making chamber installed so as to communicate with the inner wall of the freezing chamber 12 when the door 20 for the refrigerating chamber is closed. 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 , and another grill pan assembly 2 is provided in front of the first evaporator 31 in the cabinet 10 . do. 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.

For example, the grill pan assembly for a refrigerator according to the embodiment of the present invention is the grill pan assembly 1 positioned in front of the second evaporator 32 .

That is, the rear space in the freezing chamber 12 is formed to have a lower vertical height than the front space in the freezing chamber 12 due to the influence of the machine chamber 15 at the bottom thereof. The grill pan assembly 1 for the refrigerator according to the present invention can be provided. 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 . Of course, although not shown in detail, the grill pan assembly 2 provided in the space on the rear side of the refrigerating compartment 11 may also have the same structure as the grill pan assembly 1 .

As shown in FIG. 7 , the grill pan assembly 1 for the refrigerator includes a grill pan 100 , a shroud 200 , a first cold air guide passage 101 and a second cold air guide passage 102 . ) and a refrigeration fan module 410 and an ice-making fan module 420, and in particular, the grill fan 100 is provided with a temperature sensor 108 and the temperature sensor 108 is It is designed to be insulated from the evaporator 32 or the accumulator 32c.

The grill pan assembly 1 for a refrigerator 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.

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

A first cold air guide passage 101 is formed in the grill pan 100 .

The first cold air guide passage 101 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 passage 101 is formed by projecting the rear surface of the grill pan 100 forward. This is as shown in FIGS. 7 and 12 and 14 attached thereto.

At this time, the rear surface of the first cold air guide passage 101 (the surface facing the rear of the grill pan) is formed to be open, but by assembling the shroud 200 in close contact with the rear surface of the grill pan 100 , the first As the open rear surface of the cold air guide flow path 101 is closed, it is possible to provide a flow path blocked from the external environment.

Of course, although not shown, the first cold air guide passage 101 may be formed to protrude backward from the front of the shroud 200, and in this case, the grill pan 100 is the first cold air guide passage ( 101) plays a role of closing the open front surface from the external environment. Although not shown, the first cold air guide flow path 101 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

At the same time, the first cold air guide flow path 101 is formed to be rounded toward the upper side of one side (the side opposite to the side where the ice making fan module is located) while cold air flows around the upper central portion of the grill pan 100 . done so as to

That is, by forming the first cold air guide passage 101 in a rounded structure along the flow direction of cold air by rotation of a refrigeration fan 411 to be described later, cold air will flow smoothly along the first cold air guide passage 101 . made it possible

In particular, the cold air discharge side of the first cold air guide passage 101 is formed to be open to the upper surfaces of the grill fan 100 and the shroud 200 . That is, the first cold air guide passage 101 allows cold air to be discharged to the upper portion of the grill fan assembly 1, so that the connection with the conduit (eg, a cold air duct for a switching room) connected to the first cold air guide passage 101 is reduced. It is directed upward, and since the connection part is made to face upward in this way, the front and rear depth in the freezing compartment 12 can be secured as much as possible.

At this time, the lower end of the cold air duct 41 for the changeover chamber for supplying cold air to the changeover chamber 13 located above the freezing chamber 12 is connected to the open cold air discharge side portion of the first cold air guide passage 101 . (See attached Figures 9 to 11). 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).

Next, a second cold air guide passage 102 is formed in the grill pan 100 .

The second cold air guide passage 102 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 102 is formed by projecting the rear surface of the grill pan 100 forward. This is as shown in FIGS. 7 and 12 and 14 attached thereto.

At this time, the rear surface of the second cold air guide passage 102 is opened, and the rear surface of the opened second cold air guide passage 102 is closed from the external environment by the shroud 200 .

Of course, although not shown, the second cold air guide passage 102 may be formed in the shroud 200 , and in this case, the second cold air guide passage 102 is removed from the external environment by the grill fan 100 . is closed

Although not shown, the second cold air guide flow path 102 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 102 is formed from the upper side of the first cold air guide passage 101 to the side of the grill pan 100 .

At this time, the cold air discharge side of the second cold air guide flow path 102 is formed to penetrate through the side surface of the grill fan 100 to be opened.

One end of the cold air duct 51 for the ice-making chamber for supplying cold air to the ice-making chamber 21 is connected to the open end of the second cold air guide passage 102 . 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 102 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.

Next, a main cold air discharge unit 110 is formed in the grill pan 100 .

The main cold air discharge unit 110 is a hole formed to supply cold air to the freezing chamber 12 .

The main cold air discharge unit 110 is formed on the central side of the grill pan 100 when viewed from the front (or rear) of the grill pan 100 .

In particular, the main cold air discharge unit 110 is located as close to the top surface of the grill pan 100 as possible. That is, the cold air flowing through the operation of the refrigeration fan module 410 collides with the upper surface of the grill fan 100 so that it can be guided to the main cold air discharge unit 110 to the main cold air discharge unit 110 . It maximizes the amount of discharged cold air and increases the speed of the cold air so that it can be sufficiently supplied to the front side (rear wall of the freezer door) in the freezing compartment 12 .

In addition, the main cold air discharge unit 110 is formed as a tubular body with an open front while protruding toward the front of the grill pan 100 . This is as shown in the attached FIG. 7 .

A plurality of grill ribs 111 are formed in the main cold air discharge unit 110 .

The grill rib 111 is a rib for guiding the cold air discharged to the open front of the main cold air discharge unit 110 .

Next, auxiliary cold air discharge units 120 and 130 are formed in the grill pan 100 .

The auxiliary cold air discharge units 120 and 130 are tubular bodies with an open front 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 are formed along the bottom surface of the first cold air guide passage 101 . That is, the cold air can be sequentially discharged to the freezing chamber 12 through the auxiliary cold air discharge units 120 and 130 while the cold air flows along the bottom surface of the first cold air guide passage 101 . This is as shown in FIGS. 7 and 12 and 14 attached thereto.

In particular, the 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 101 . That is, the auxiliary cold air discharging units 120 and 130 are positioned below the main cold air discharging unit 110 and located on both sides with respect to the main cold air discharging unit 110 , respectively, to supply cold air into the freezing chamber 12 . By doing so, the supply of cold air to the middle portion in the freezing compartment 12 can be made sufficiently.

The auxiliary cold air discharge units 120 and 130 are first auxiliary cold air discharge units 120 formed on either side (right side in the drawing when the grill pan is viewed from the front) of the bottom side portion in the first cold air guide flow path 101 and A second auxiliary cold air discharge unit 130 formed on the other side (left side in the drawing when the grill pan is viewed from the front) is included. As a result, cold air may be supplied to the freezing chamber 12 while sequentially passing through the first auxiliary cold air discharge unit 120 and the second auxiliary cold air discharge unit 130 while flowing along the first cold air guide flow path 101 . .

In addition, 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.

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.

Next, the grill pan 100 is provided with a suction guide 140 .

The suction guide 140 is configured to guide the recovery flow of the cold air flowing through the freezing chamber 12 .

The suction guide 140 is formed at the lower end of the grill pan 100 so that the cold air recovered after circulating in the freezing compartment 12 flows into the lower end of the second evaporator 32 .

In addition, the suction guide 140 is formed to be round or bent in the same structure as the bottom surface of the freezing chamber 12 and partially cover the bottom surface of the freezing chamber 12 .

That is, the cold air flowing along the bottom of the freezing chamber 12 can be guided by the suction guide 140 to smoothly flow to the cold air inlet side (bottom surface) of the second evaporator 32 .

Next, a first mounting end 107 is formed on the grill pan 100 .

The first mounting end 107 is a portion formed to be mounted on the front side of the flow path opening/closing module 105, which will be described later.

Such a first mounting end 107 is formed on the cold air discharge side of the first cold air guide flow path 101 . That is, the cold air flowing along the first cold air guide passage 101 passes through the first mounting end 107 and is discharged toward the cold air discharge side. This is as shown in FIGS. 7 and 9 and 10 and 12 and 14 and 15 attached thereto.

In particular, the first mounting end 107 is positioned adjacent to the cold air outlet side of the first cold air guide passage 101 and is positioned higher than the second evaporator 32 . Through this, freezing of the flow path opening/closing module 105 mounted on the mounting end 107 is prevented.

In addition, the first mounting end 107 is formed by expanding a portion of the first cold air guide passage 101 of the grill pan 100 compared to other portions.

Next, the grill pan 100 is provided with a flow path opening/closing module 105 .

The flow path opening/closing module 105 is configured to open and close to selectively block the cold air flowing along the first cold air guide flow path 101 from being discharged to the cold air outlet side of the first cold air guide flow path 101 .

That is, the cold air supplied to the switching chamber 13 along the first cold air guide passage 101 can be intermittently supplied as needed. Through this, the inside of the switching chamber 13 can be stored under a different temperature condition than that of the freezing chamber 12 .

The flow path opening/closing module 105 is configured to block the flow of cold air passing through the corresponding portion along the first cold air guide flow path 101 while being mounted on the first mounting end 107 .

The flow path opening/closing module 105 is configured to include a damper case 105a, an opening/closing damper 105b, and a damper motor 105c as shown in FIGS. 15 and 19 to 22 .

Here, the damper case 105a is installed to block the inside of the first mounting end 107 and has a rectangular frame structure in which a through hole 105d is formed inside, and the opening/closing damper 105b is the damper case It is installed in the 105a to open and close the through hole 105d, and the damper motor 105c operates the opening/closing damper 105b.

In this case, the damper motor 105c may be a motor, and the opening/closing damper 105b may be formed as a plate that blocks or opens the through hole 105d while rotating while being shaft-coupled to the motor.

Of course, although not shown, the flow path opening/closing module 105 may be configured to forcibly block or open the first cold air guide flow path 101 by a solenoid or a cylinder, etc. can

Meanwhile, as shown in FIG. 15 , the flow path opening/closing module 105 is mounted on the first mounting end 107 while being wrapped in the damper cover 106 .

The damper cover 106 is configured to protect the operation motor 105c of the flow path opening/closing module 105 from cold air.

This damper cover 106 is formed of a heat insulating material. That is, the damper cover 106 made of the insulating material is installed to surround the flow path opening/closing module 105, so that the flow path opening/closing module (particularly, the operation motor) 105 is connected to the shroud 200 or the grill pan 100. It is designed not to be affected by the cold air conducted over the surface of the

In this case, the damper cover 106 may be formed of Styrofoam, rubber or silicone, or may be formed of a porous foam material (eg, foam rubber, etc.). Of course, it may be formed of other insulating materials not described.

The damper cover 106 may be divided into a front damper cover and a rear damper cover based on the center. That is, after the passage opening/closing module 105 is mounted on the damper cover on one side, the damper cover on the other side is covered.

The damper cover 106 has a cold air inlet 106a and a cold air outlet 106b (see attached FIG. 9).

The cold air inlet 106a is formed to pass through the bottom wall of the damper cover 106 and is positioned to communicate with the inside of the first cooling guide flow path 101 .

The cold air outlet 106b is formed through the upper wall of the damper cover 106 and the cold air duct 41 for the switching room is connected to the cold air outlet side of the first cold air guide flow path 101 .

In particular, on the bottom surface of the damper cover 106, the support end 106c is formed to be stepped around the cold air inlet 106a. A portion of the bottom surface of the damper case 105a is accommodated in the support end 106c. That is, by the coupling structure between the support end 106c and the lower surface of the damper case 105a, the flow path opening/closing module 105 is installed in the correct position in the damper cover 106 and the flow is prevented.

At the same time, a motor accommodating groove 106d in which the operation motor 105c of the flow path opening/closing module 105 is accommodated is concavely formed in the damper cover 106 . That is, the operation motor 105c is insulated from the external environment while being mounted in the motor accommodating groove 106d.

Next, a mounting part 150 is formed on the grill pan 100 .

The mounting part 150 is a portion provided for mounting the temperature sensor 108 . At this time, the temperature sensor 108 is a sensor for detecting the temperature in the freezing compartment (120).

The mounting part 150 is formed on the side of the part where the first mounting end 107 is formed among each part of the grill pan 100 . This is as shown in the attached FIG. 8 .

That is, by locating the mounting part 150 at the same height as the first mounting end 107 , the temperature sensor 108 installed in the mounting part 150 can be as far as possible from the second evaporator 32 .

Of course, since the heat shielding plate 33 (refer to the attached FIG. 5) is provided on the front surface of the second evaporator 32, the measurement error caused by the temperature sensor by the second evaporator 32 is minimized.

In addition, the mounting part 150 is formed to more protrude from the front side of the grill pan 100, and the mounting groove 151 is concavely formed on the rear surface. The temperature sensor 108 is received and coupled in the mounting groove 151 .

At the same time, a gripping end 152 for restraining the temperature sensor 108 is formed in the mounting groove 151 . That is, the temperature sensor 108 is gripped and fixed to the gripping end 152 .

The gripping end 152 is formed to protrude inwardly from at least one wall surface in the mounting groove 151 . That is, since each gripping end 152 grips at least one side of the temperature sensor 108 , the temperature sensor 108 can be stably maintained in the mounting groove 151 .

In this case, two or more gripping ends 152 may be formed in plurality, may be formed only on one wall surface in the mounting groove 152 , or a plurality of gripping ends 152 may be formed to form a pair with each other.

In addition, exposed holes 153 and 154 are formed in the mounting part 150 . That is, the temperature sensor 108 in the mounting groove 151 can be exposed to the freezing chamber 12 through the exposure holes 153 and 154 .

In this case, two or more of the exposed holes 153 and 154 may be formed as shown in FIG. 8 .

These exposed holes 153 and 154 include front exposed holes 153 penetrating through the front surface of the mounting part 150 .

That is, as the temperature sensor 108 is exposed into the freezing chamber 12 through the formation of the front exposure hole 153 , it is possible to accurately sense the temperature of the cold air in the freezing chamber 12 .

In addition, the exposure holes 153 and 154 include side exposure holes 154 penetrating both sides of the mounting part 150 .

That is, the temperature sensor 108 in the mounting part 150 can accurately recognize the temperature of the cold air flowing in the horizontal direction in the freezing compartment 12 through the additional formation of the side exposed hole 154 .

In addition, a wire receiving groove 155 (see attached FIG. 13 ) is formed in the mounting part 150 .

The wire accommodating groove 155 is a groove formed to accommodate the power wire 108a of the temperature sensor 108 .

That is, by allowing the power line 108a to be fixed while being accommodated in the wire accommodating groove 155, a short circuit with the temperature sensor 108 that may occur as the power line 108a flows undesirably is prevented. it was made to be

The wire accommodating groove 155 is formed to extend downward from the bottom of the mounting groove 151 and then bent to either side, thereby preventing the power supply line 108a from being short-circuited from the temperature sensor 108. The power supply line 108a can be easily drawn out.

Next, the grill pan 100 is provided with a heat insulating part 190 (see attached FIG. 15 ).

The heat insulating part 190 is configured to protect the temperature sensor 108 installed in the grill pan 100 and to insulate a portion where the temperature sensor 108 is installed from the shroud 200 .

That is, since the temperature sensor 108 is concavely mounted in the mounting groove 151 , it is exposed rearwardly through the open portion of the mounting groove 151 . Of course, the rear surface of the grill pan 100 is configured to cover while a shroud 200 to be described later is coupled, but the low-temperature heat generated by the second evaporator 32 located at the rear of the shroud 200 is When the shroud 200 is conducted, when the temperature sensor 108 is affected by such low-temperature heat, a sensing failure that incorrectly determines the temperature of the freezing compartment 12 may occur.

In particular, a portion where the temperature sensor 108 is located is an upper portion of the second evaporator 32, but an accumulator 32c is located (see attached FIG. 18) opposite this portion, and such an accumulator 32c ) has a lower temperature than that of the freezing compartment 12, so that the temperature sensor 108 may generate a sensing error for the temperature of the freezing compartment 12 under the influence of the accumulator 32c.

Considering this, even if low-temperature heat is conducted from the second evaporator 32 to the shroud 200, the low-temperature heat is blocked from being provided to the temperature sensor 108 by the heat insulating part 190, and at the same time, the accumulator Since the low-temperature heat of 32c is blocked from being provided to the temperature sensor 108, more accurate temperature sensing of the freezing compartment 12 is possible.

The heat insulating part 190 is formed of a plate material covering a portion of the rear surface of the grill pan 100 in which the mounting groove 150 is formed.

In particular, the heat insulating portion 190 is formed to have a larger width than that of the mounting groove 150 . Accordingly, by reducing the heat conduction to the adjacent portion of the temperature sensor 108 , the reliability of the sensing value of the temperature sensor 108 may be improved.

The heat insulating part 190 is integrally formed with the damper cover 106 . This is as shown in the attached FIG. 7 .

That is, by installing the damper cover 106 on the grill pan 100 or the shroud 200 , the heat insulating part 190 covers the mounting groove 151 .

In addition, the heat insulating part 190 is formed of the same insulating material as the damper cover 106 (Styrofoam, rubber, silicone, or foamed rubber).

In addition, the heat insulating part 190 may be integrally formed with the front damper cover installed on the grill pan 100 or integrally formed with the rear damper cover installed on the shroud 200 .

However, considering that the mounting groove 151 to which the temperature sensor 108 is mounted is formed in the grill pan 100 , the heat insulating part 190 is integrated into the front damper cover mounted on the grill pan 100 . more preferably.

In particular, the heat insulating part 190 is formed to protrude from the side surface of the damper cover 106 .

That is, the heat insulating part 190 extends from the damper cover 106 toward the side, so that the mounting groove 151 of the mounting part 150 positioned side by side with the first mounting end 107 is formed in the heat insulating part 190 . so that it can be easily covered.

At the same time, the heat insulating part receiving groove 109 is concavely formed on the rear surface of the grill pan 100 where the mounting groove 151 is formed so that the heat insulating part 190 is accommodated.

That is, the heat insulating part accommodating groove 109 is additionally formed so that the heat insulating part 190 is accommodated, so that it can be easily installed in the proper position of the heat insulating part 190 .

Of course, the heat insulating part 190 may be configured to protect the temperature sensor 108 while being provided as a separate configuration from the damper cover 106 . However, if the heat insulating part 190 is provided separately from the damper cover 106, the heat insulating part 190 can be fixed at a specific position until the assembly between the grill pan 100 and the shroud 200 is completed. In addition to having to add a separate structure for this, the inconvenience of having to add work for this may be caused.

Considering this, since the heat insulating part 190 is integrally formed with the damper cover 106 , an increase in manufacturing cost and inconvenience in assembling caused by the separate manufacture of the heat insulating part 190 can be eliminated.

Next, a first seating portion 160 is formed on the grill pan 100 .

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 protrude from the surface (rear surface) of the grill pan 100 to the front of the grill pan 100 , and the first seating portion 160 has a portion of the refrigeration fan module 410 . is installed in such a way that

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 in the front-rear direction. will be. 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 vertical height of the grill pan 100 and when viewed based on the left and right length of the grill pan 100 . It is formed approximately in the central region.

In particular, the main cold air discharge unit 110 is formed to cross the upper end of the first seating unit 160 , and the cold air blown by the refrigeration fan module 410 is the main cold air discharge unit 110 . to be sufficiently discharged into the freezing chamber 12 through the

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 on the refrigeration fan 411 when the refrigeration fan 411 is excessively close to the second evaporator 32, the refrigeration fan 411 may be spaced apart from each other by at least 3 mm in the front-back direction. It is preferable to determine the depression depth of the first seating part 160 .

The upper surface of the first seating part 160 has a structure that is opened upward. That is, the upper end of the refrigeration fan module 410 installed in the first seating unit 160 is positioned opposite the main cold air discharge unit 110 and is exposed to the main cold air discharge unit 110, After passing through the first inlet hole 210 , the cold air introduced between the grill pan 100 and the shroud 200 can be sufficiently discharged to the main cold air outlet 110 .

At this time, the upper end of the refrigeration fan module 410 exposed through the open upper surface of the first seating unit 160 is high enough not to completely block the main cold air discharge unit 110 (the upper part of the main cold air discharge unit). It should be positioned only to a height that the wall does not reach). That is, the cold air flowing in the circumferential direction of the refrigeration fan module 410 can have a sufficient discharge force in the process of passing through the main cold air discharge unit 110 , so that the cold air reaches the front surface of the cabinet 10 . This was done to ensure a smooth supply.

If the refrigeration fan module 410 is positioned to completely block the main cold air discharge unit 110, the flow rate of cold air becomes rather slow, so that the cold air supply to the front of the cabinet 10 may not be sufficiently achieved. have.

Therefore, due to the above-described structure of the first seating part 160 and the arrangement of the refrigeration fan module 410 seated therein, approximately of the cold air blown into the first cold air guide passage 101 by the refrigeration fan module 410 is approximately About half of the cold air can be discharged to the main cold air discharge unit 110, and the remaining cold air flows along the first cold air guide flow path 101, and the two auxiliary cold air discharge units 120 and 130, the switching chamber 13, or the communication It is discharged to the flow path (183).

Next, a second seating portion 170 is formed on the grill pan 100 .

The second seating portion 170 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 .

On the other hand, the first seating portion 160 and the second seating portion 170 is configured to be positioned further above the upper surface position of the second evaporator (32).

That is, the positions of the refrigeration fan module 410 and the ice-making fan module 420 that are seated on the first seating part 160 and the second seating part 170 are positioned higher than the upper surface of the second evaporator 32 . By doing so, it is possible to prevent malfunction (freezing) of the respective fan modules 410 and 420 that may be caused by the proximity of the second evaporator 32 and the respective fan modules 410 and 420 .

At this time, the upper surface of the second evaporator 32 may be a portion located at the uppermost side among the refrigerant pipes 32a constituting the second evaporator 32, and a heat exchange fin ( 32b) may be the upper end.

In the embodiment of the present invention, it is assumed that the upper surface of the second evaporator 32 is the upper end of the heat exchange fin 32b. This is as shown in the attached FIG. 18 . Accordingly, the phenomenon in which each of the fan modules 410 and 420 is frozen under the influence of the second evaporator 32 is reduced.

In particular, the portion of the second evaporator 32 adjacent to each of the fan modules 410 and 420 may be configured such that the heat exchange fin 32b does not exist, thereby reducing the freezing phenomenon of each of the fan modules 410 and 420 .

At the same time, a heat barrier plate 33 (see attached FIG. 5 ) is provided on the front surface of the second evaporator 32 , and low-temperature cold air emitted from the second evaporator 32 by the heat barrier plate 33 . is prevented from being conducted to the shroud 200 .

Next, partition ribs 181 and 182 are formed in the grill pan 100 .

The partition ribs 181 and 182 are formed to cross the boundary between the first cold air guide passage 101 and the second cold air guide passage 102 to partition the two cold air guide passages 101 and 102 from each other.

The partition ribs 181 and 182 are formed to protrude from the rear surface of the grill pan 100 toward the front surface of the shroud 200 . When the grill pan 100 and the shroud 200 are coupled, the rear surfaces of the partition ribs 181 and 182 are made to be in close contact with the front surface of the shroud 200 .

In particular, a communication passage 183 is formed in the partition ribs 181 and 182 (see attached FIG. 17 ).

The communication passage 183 is an open portion formed in the partition ribs 181 and 182 to supply the cold air in the second cold air guide passage 102 toward the main cold air discharge unit 110 in the first cold air guide passage 101 .

At this time, the partition ribs 181 and 182 are divided into a first partition rib 181 and a second partition rib 182, and the communication passage 183 is an open portion formed between the two partition ribs 181 and 182. is composed

That is, the divided portions of the two partitioning ribs 181 and 182 are spaced apart from each other to form a communication passage 183 , and cold air can pass through the communication passage (spaced portion) 183 .

Here, the first partition rib 181 is formed to extend downward from the top surface of the grill pan 100 . This is as shown in the attached FIG. 17 .

That is, the first compartment rib 181 is configured to block 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 compartment rib 181 , 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 102 .

In addition, the first compartment rib 181 may be rounded to surround a portion of the upper periphery (the perimeter of the ice-making fan module) of the second seating portion 170 .

In addition, the second partition rib 182 is formed to extend upwardly from the bottom surface in the first cold air guide passage 101 among the rear surfaces of the grill pan 100 .

That is, the second compartment rib 182 blocks the lower portion from the central portion between the ice-making fan module 420 and the freezing fan module 410 .

The main cold air discharge unit 110 while preventing the cold air provided from the ice making fan module 420 from being directed to the freezing fan module 410 in the first cold air guide flow path 101 by the structure of the second compartment rib 182. can flow smoothly toward

In particular, the second compartment rib 182 is formed to be round to surround a part of the circumference of the second seating part 170 (the circumference of the ice-making fan module). This is as shown in the attached FIG. 17 .

That is, the cold air blown from the ice-making fan module 420 through the round structure of the second compartment rib 182 smoothly goes to one end portion of the main cold air outlet 110 (the portion on which the ice-making fan module is located). made to be movable.

Next, the shroud 200 will be described.

The shroud 200 is a portion forming a rear wall of the grill pan assembly 1 for a refrigerator.

The shroud 200 is located in front of the second evaporator 32 installed adjacent to the rear wall surface in the cabinet 10 . 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 , and is formed to be spaced apart from the grill pan 100 so that a flow path for cold air flow can be created.

A first inlet hole 210 and a second inlet hole 220 are formed through the shroud 200 . This is as shown in the accompanying Figures 23 and 24.

The two inlet holes 210 and 220 allow the cold air heat-exchanged through the second evaporator 32 located at the rear in the freezing compartment 12 to be introduced into the space between the grill fan 100 and the shroud 200 . formed hole. That is, the cold air circulated in the freezing chamber 12 passes through the second evaporator 32 and then passes through the first inlet hole 210 or the second inlet hole 220 to the freezing fan module 410 or the ice making fan module. 420 may be provided.

In particular, the second evaporator 32 is configured such that the upper end thereof reaches only a lower position than the formation position of the first inlet hole 210 and the second inlet hole 220 .

That is, the first inlet hole 210 and the second inlet hole 220 are positioned higher than the upper surface (the upper end of the heat exchange fin) of the second evaporator 32 , and thereby the refrigeration installed in the grill pan 100 . The fan module 410 and the ice-making fan module 420 may also be positioned higher than the upper surface of the second evaporator 32 .

At this time, the upper surface of the second evaporator 32 may be a portion located at the uppermost side among the refrigerant pipes 32a constituting the second evaporator 32, and a heat exchange fin ( 32b) may be the upper end.

In the embodiment of the present invention, it is assumed that the upper surface of the second evaporator 32 is the upper end of the heat exchange fin 32b. This is as shown in the attached FIG. 18 . Accordingly, it is possible to reduce the phenomenon that each fan module (410, 420) is frozen by the influence of the second evaporator (32).

Next, a second mounting end 207 is formed on the shroud 200 .

The second mounting end 207 is a portion formed to be mounted on the rear side of the flow path opening/closing module 105 .

Such a second mounting end 207 is formed in a portion opposite to the first mounting end 107 of the grill pan 100, whereby the first mounting end 107 and the second mounting end 207 are mutually The flow path opening/closing module 105 is accommodated while forming a pair. This is as shown in FIGS. 7 and 9 and 23 and 24 attached thereto.

Next, the support end 208 is formed on the shroud 200 .

The support end 208 is configured to support the rear surface of the heat insulating part 190 .

That is, since the heat insulating part 190 is integrally formed with the damper cover 106 , if the damper cover 106 is mounted between the grill pan 100 and the shroud 200 , the heat insulating part 190 is heated. It may be positioned to obstruct the sensor 108 .

However, the heat insulating part 190 is simply seated in the heat insulating part accommodating groove 109 of the grill pan 100 and is not in close contact with it, so a gap between the heat insulating part 190 and the surface of the heat insulating part accommodating groove 109 is may occur.

Accordingly, when the support end 208 is additionally formed on the shroud 200 to couple the shroud 200 to the grill pan 100 , the support end 208 is the heat insulating part 190 . While supporting the rear surface, the heat insulating part 190 can be accurately adhered to the surface of the heat insulating part accommodating groove 109 of the grill pan 100 .

Meanwhile, the grill pan 100 and the shroud 200 are formed to have upper surfaces 101 and 201, respectively, and the upper surfaces 101 and 201 are coupled to each other in an overlapping state.

Next, the refrigeration fan module 410 will be described with reference to FIGS. 25 and 26 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 101 .

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, and the fan motor 413 of the refrigeration fan 411 is fixedly installed.

The first installation frame 412 is configured to be fastened to the grill pan 100 using a plurality of fastening ribs 412a. In this case, each of the fastening ribs 412a is formed at a position in consideration of the size and wind direction of the refrigeration fan 411 .

Next, the ice making fan module 420 will be described with reference to FIGS. 25 and 26 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 102 .

The ice-making fan module 420 includes an ice-making fan 421 , a second installation frame 422 , and a fan motor 423 .

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, and the fan motor 423 of the ice-making fan 421 is fixedly installed.

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

In particular, the ice-making fan module 420 is configured to be located closer to each of the partition ribs 181 and 182 (see attached FIG. 15 ) compared to the cold air outlet side of the second cold air guide flow path 102 .

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 (open portion) of the second cold air guide passage 102 by a sufficient distance, the second cold air guide passage 102 . ), the cold air passing through the cold air outlet side cannot smoothly pass through the cold air outlet side due to resistance caused by the cold air flow rotating along the rotational direction of the ice making fan 421 and turbulence can be prevented. 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.

Hereinafter, the temperature control process of each storage compartment 12 , 13 , and 21 by the operation of the grill pan assembly 1 for a refrigerator 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. 27 to 30 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 105b constituting the flow path opening/closing module 105 is the through hole 105d of the damper case 105a ), so that the cold air outlet side of the first cold air guide flow path 101 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 .

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 101 and then flows along the first cold air guide passage 101. , is continuously supplied to the upper space in the freezing compartment 12 through the main cold air outlet 110 formed in the grill pan 100 .

At the same time, the remaining cold air that has not been discharged to the main cold air outlet 110 among the cold air flowing by the blowing force by the refrigerating fan 411 flows along the first cold air guide passage 101 , and thus the first cold air Intermediate space in the freezing chamber 12 while sequentially passing through the first auxiliary cold air outlet 120 and the second auxiliary cold air outlet 130 formed in the first cold air guide passage 101 while flowing along the guide passage 101 . is supplied with

At this time, about half or more of the cold air passing through the first inlet hole 210 is discharged to the main cold air outlet 110 , and the remaining cold air is the first auxiliary cold air outlet 120 and the second auxiliary cold air outlet 130 ). is emitted as

In particular, considering that the cold air outlet side of the first cold air guide passage 101 is closed by the passage opening/closing module 105, the cold air flowing in the first cold air guide passage 101 is each auxiliary cold air. Most of it is supplied to the intermediate space in the freezing compartment 12 through the outlets 120 and 130 , and some is supplied to the upper space in the freezing chamber 12 through the main cold air outlet 110 while rising again.

In addition, the cold air supplied into the freezing chamber 12 through each of the cold air outlets 110, 120, 130 flows in the freezing chamber 12 and then receives the guidance of the suction guide 140 formed in the grill fan 100 and the second evaporator ( 32) is returned to the air inlet side.

In particular, considering that the suction guide 140 is formed to be inclined (or round) in the same shape as the wall surface formed by the bottom of the rear side of the freezing chamber 12, the machine room 15 is inclined after the freezing chamber 12 flows. Cold air flowing along the wall may be guided by the suction guide 140 to smoothly flow toward 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 108 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, 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 102 is generated by the operation of the ice making fan 421 .

The cold air generated by the operation of the ice-making fan 421 is partially supplied to the first cold air guide passage 101 through the communication passage 183 , and the rest is for the ice-making chamber connected to the second cold air guide passage 102 . The cold air is supplied to the ice making chamber 21 through the duct 51 .

That is, the cold air that has passed through the second inlet hole 220 and blown into the first area 102a of the second cold air guide passage 102 passes through the communication passage 183 and is supplied to the first cold air guide passage 101 . The cold air passed through the second inlet hole 220 and blown into the second region 102b of the second cold air guide passage 102 passes through the auxiliary passage 184 and is supplied to the first cold air guide passage 101 . The cold air passed through the second inlet hole 220 and blown into the third region 102c of the second cold air guide passage 102 is connected to the cold air discharge side of the second cold air guide passage 102. 51 ) to the ice making chamber 21 .

Accordingly, 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 sufficient cold air can be supplied.

The flow of cold air when the freezing operation and the ice making operation are simultaneously performed is as shown in FIGS. 31 and 32 attached thereto.

On the other hand, while the freezing operation of the freezing compartment 12 is performed, the cold air of the freezing compartment 12 is conducted over the surfaces of the grill pan 100 and the shroud 200 in a process in which the circulation operation of the cold air is repeated.

However, the flow path opening/closing module 105 is configured to be insulated from the grill pan 100 or the shroud 200 while being wrapped in the damper cover 106 . Accordingly, it is possible to prevent the operation failure phenomenon caused by the operation motor 105c constituting the flow path opening/closing module 105 generating a malfunction due to a low temperature or the opening/closing damper 105b being frozen.

In particular, since the insulating part 190 integrally formed with the damper cover 106 is positioned to block the mounting groove 151 in which the temperature sensor 108 is mounted, the second evaporator 32 is passed through the shroud 200 . ) is prevented from being conducted to the temperature sensor 108 and the low-temperature heat emitted by the accumulator 32c is blocked from being provided to the temperature sensor 108 .

At the same time, since the front and both sides of the mounting part 150 to which the temperature sensor 108 is mounted are respectively formed with a front exposed hole 153 and a side exposed hole 154, the temperature sensor 108 is installed in the freezing compartment 12 ) can be accurately measured.

Next, a process for controlling the temperature of the switching chamber 13 will be described with reference to FIGS. 33 to 36 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 105 .

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. The flow path opening/closing module 105 is operated so that the opening/closing damper 105b opens the through hole 105d of the damper case 105a by the operation of the operation motor 105c.

And, when the refrigeration fan 411 is operated in the state in which the through hole 105d is opened, the air present in the rear side in the freezing chamber 12 is blown by the air blowing force by the refrigeration fan 411 in the second evaporator 32 ) through which heat is exchanged. Of course, the passage hole 105d may be opened while the flow path opening/closing module 105 is operated while the refrigeration fan 411 is operating.

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 101 formed in the grill fan 100, and then the first cold air It flows along the guide flow path 101 and is continuously supplied to the upper space in the freezing chamber 12 through the main cold air outlet 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 outlet 110 among the cold air flowing by the blowing force by the refrigerating fan 411 flows along the first cold air guide passage 101 , and thus the first cold air Intermediate space in the freezing chamber 12 while sequentially passing through the first auxiliary cold air outlet 120 and the second auxiliary cold air outlet 130 formed in the first cold air guide passage 101 while flowing along the guide passage 101 In addition to being supplied to the , the rest of the cold air passes through the through hole 105d of the damper case 105a located at the mounting ends 107 and 207 of the first cold air guide flow path 101, and is for a changeover room connected to the cold air outlet side. The cold air is supplied to the switching chamber 13 through the duct 41 .

At this time, the cold air discharged to the main cold air outlet 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 101 is closed, and the first auxiliary cold air outlet The cold air discharged to 120 and the second auxiliary cold air outlet 130 is discharged only 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 103, and then the return duct 42 for the change-over room connected to the change-over room 13 (Figs. 33 and 34 attached). Refer to), it is recovered to the air inlet side of the second evaporator 32 .

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 .

If the inside of the switching chamber 13 reaches a set temperature, the operation motor 105c of the flow path opening/closing module 105 is operated under the control of a controller (not shown) to rotate the opening/closing damper 105b. .

At this time, the operation motor 105c rotates the opening/closing damper 105b in the closing direction, whereby the opening/closing damper 105b is in close contact with the surface of the cold air outlet side of the passage hole 105d among the surfaces of the damper case 105a. to close the through hole (105d).

Due to the closure of the through hole 105d, the cold air supply to the switching chamber 13 is no longer stopped.

Of course, if the inside of the switching chamber 13 rises to a temperature above the set temperature range, the operation motor 105c of the flow path opening/closing module 105 is operated under the control of the control unit, and the opening/closing damper 105b is rotated to rotate the through hole 105d. will open

Therefore, the inside of the switching chamber 13 can always maintain the set temperature range by the repetitive operation of the flow path opening/closing module 105 described above.

Next, a process for controlling the temperature of the ice-making chamber 21 will be described with reference to FIGS. 37 to 40 attached thereto.

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 102 , and continues to flow along the second cold air guide passage 102 .

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 102 is provided to the cold air duct 51 for the ice-making chamber connected to the second cold air guide passage 102, and then the cold air duct 51 for the ice-making chamber is connected. 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 attached Figures 37 and 40.

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).

The supply of cold air to the ice-making chamber 21 may be controlled differently according to the amount of ice stored in the ice-making chamber 21 or a manual operation of the user.

For example, when it is confirmed that more than a set amount of ice is stored or the user forcibly stops the ice making operation, the operation of the ice making fan 421 is stopped, thereby stopping the supply of cold air to the ice making chamber 21 .

In addition, while cold air is supplied to the ice-making chamber 21 along the second cold air guide flow path 102 by the operation of the ice-making fan 421 , a part of the cold air is discharged to the main cold air outlet 110 and the freezing chamber 12 ) can also be supplied.

That is, some of the cold air flowing in the opposite direction to the second cold air guide passage 102 among the cold air passing through the second inlet hole 220 flows along the rotation direction of the ice making fan 421 while the flow is guided. After flowing into the first cold air guide passage 101 through the communication passage 183 between the two partition ribs 181 and 182, the cold air is supplied to the freezing chamber 12 through the main cold air outlet 110 located on the corresponding direction.

Accordingly, a sufficient amount of cold air can be supplied to the freezing chamber 12 .

As a result, in the grill pan assembly 1 for a refrigerator of the present invention, a temperature sensing failure due to the influence of the second evaporator 32 and the accumulator 32c is prevented by providing the heat insulating part 190 covering the temperature sensor 108 . Thus, accurate temperature control of the freezing compartment 12 is possible.

In particular, the grill pan assembly 1 for a refrigerator according to the present invention can be easily manufactured and assembled because the heat insulating part 190 is integrally formed with the damper cover 106 .

In addition, in the refrigerator grill pan assembly 1 of the present invention, sensing by the temperature sensor 108 is configured so that the heat insulating part 190 is closely attached to the heat insulating part accommodating groove 109 while maintaining airtightness. Reliability can be improved.

In addition, in the grill fan assembly 1 for a refrigerator of the present invention, since the power line 108a connected to the temperature sensor 108 can always be placed in the correct position, the power line 180a is short-circuited from the temperature sensor 108 . is prevented from becoming

In addition, in the grill pan assembly 1 for a refrigerator of the present invention, a heat blocking plate 33 is additionally provided between the second evaporator 32 and the grill pan assembly, so that freezing of the flow path opening/closing module 105 can be prevented. In addition, the sensing reliability of the temperature sensor 108 may be improved.

Claims (20)

a shroud positioned in front of an evaporator provided on a rear wall of a cabinet having a switching chamber and a freezing chamber, the shroud having an inlet hole for introducing cool air passing through the evaporator;
a grill fan coupled to the front surface of the shroud and having a cold air guide passage guiding cold air to flow to the switching chamber on the rear surface, and a cold air outlet for discharging cold air to the freezing chamber in the cold air guide passage;
a fan module installed between the grill fan and the shroud to suck cool air through the inlet hole and then blow it so that it flows along the cold air guide passage;
a flow passage opening/closing module installed in the cold air guide passage to selectively block the cold air flow to the switching chamber;
a temperature sensor that is installed in the grill pan and senses the temperature of the freezing compartment;
and an insulator for blocking the temperature of the temperature sensor from being supplied to the temperature sensor of the evaporator or of an accumulator connected to the evaporator. The method of claim 1,
A grill pan assembly for a refrigerator, characterized in that the grill pan is formed with a mounting portion to which the temperature sensor is mounted. 3. The method of claim 2,
The mounting portion is formed to more protrude from the front surface of the grill pan, and a mounting groove is formed in a concave recess on the rear surface,
The grill pan assembly for a refrigerator, characterized in that the temperature sensor is inserted and mounted in the mounting groove. 4. The method of claim 3,
A grill pan assembly for a refrigerator, characterized in that a gripping end for gripping the temperature sensor is formed in the mounting groove. 5. The method of claim 4,
The grill pan assembly for a refrigerator, characterized in that the gripping end is formed to protrude inwardly from at least one wall surface in the mounting groove. 4. The method of claim 3,
and an exposure hole is formed in the mounting part so that the temperature sensor in the mounting groove is exposed to the freezing chamber. 7. The method of claim 6,
The grill pan assembly for a refrigerator, characterized in that two or more exposed holes are formed in plurality. 8. The method of claim 7,
The grill pan assembly for a refrigerator, characterized in that the exposed hole includes a front exposed hole that is formed through the front surface of the mounting part. 8. The method of claim 7,
The exposed hole is a grill pan assembly for a refrigerator, characterized in that it includes side exposed holes formed through both sides of the mounting portion. 4. The method of claim 3,
The grill pan assembly for a refrigerator, characterized in that the mounting portion is formed with a wire receiving groove for receiving the power wire of the temperature sensor. 11. The method of claim 10,
The electric wire accommodating groove is formed to guide the power wire toward the side of the grill pan while extending from a bottom surface of the mounting groove. According to claim 1,
A mounting end on which the flow path opening/closing module is mounted is formed in the cold air guide flow path,
The grill pan assembly for a refrigerator, characterized in that the mounting portion is formed on the side of the mounting end. 13. The method of claim 12,
A grill pan assembly for a refrigerator, characterized in that the mounting end is provided with a damper cover surrounding the flow path opening and closing module. 14. The method of claim 13,
The grill pan assembly for a refrigerator, characterized in that the heat insulating part is integrally formed with the damper cover. 15. The method of claim 14,
The grill pan assembly for a refrigerator, characterized in that the heat insulating portion is formed to protrude from the side of the damper cover. 16. The method of claim 15,
A grill pan assembly for a refrigerator, characterized in that a support end is formed on the front surface of the shroud for supporting the rear surface of the heat insulating part. 15. The method of claim 14,
The grill pan assembly for a refrigerator, characterized in that the damper cover and the heat insulating part are formed of a heat insulating material. 13. The method of claim 12,
A receiving groove for accommodating the heat insulating part is formed on the rear surface of the grill pan,
The grill pan assembly for a refrigerator, characterized in that the mounting groove of the mounting part is formed in the receiving groove and the temperature sensor is exposed to the front of the grill pan. The method of claim 1,
A grill pan assembly for a refrigerator, characterized in that a heat shield for blocking the evaporator is provided between opposite surfaces between the evaporator and the shroud. The method of claim 1,
The flow path opening/closing module is installed to be wrapped with a damper cover,
The grill pan assembly for a refrigerator, characterized in that the heat insulating part is integrally formed with the damper cover.

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