KR102200537B1 - Duct assembly and refrigerator - Google Patents

Abstract

The present invention relates to a duct assembly and a refrigerator, in particular, comprising a third duct connecting the first inlet and the second inlet, and the holding space portion holding at least a part of the air sucked through the first inlet is a third It is formed to be in communication with the duct, and when the blowing fan that circulates cold air is stopped, the temperature of the first and second storage chambers is further reduced by minimizing the air inhaled through the first inlet and entering the second storage chamber through the second inlet. It relates to a duct assembly and a refrigerator that can be effectively independently maintained.

Description

Duct assembly and refrigerator}

The present invention relates to a duct assembly and a refrigerator, in particular, comprising a third duct connecting the first inlet and the second inlet, and the holding space portion holding at least a part of the air sucked through the first inlet is a third It relates to a duct assembly formed to communicate with the duct and a refrigerator.

In general, a refrigerator or kimchi refrigerator (hereinafter referred to as a refrigerator) constitutes a refrigeration cycle with a compressor, a condenser, an expansion device, and an evaporator as major components, and between the heater and the air inside the storage compartment separately provided around the evaporator and storage compartment. This is a device for storing stored materials stored in a storage room through heat transfer in a aging or low temperature condition as necessary.

The refrigerator is a direct cooling method in which a storage room is cooled using a pipe-type evaporator arranged to surround the outer surface of the storage space according to the cooling method, and an evaporator with cooling fins and a blower fan are mounted on one side of the storage room, and a blowing fan is installed. It is divided into an indirect cooling method that drives and supplies cold air to the storage room through a cold air flow path. On the other hand, in recent years, a mixed refrigerator in which a direct-cooled storage room and an intercooled storage room are mixed and applied has been proposed.

As shown in Korean Unexamined Patent Publication No. 2014-0004420, when two or more indirect cooling storage chambers are formed, each of the cold air ducts supplying cold air to the first and second storage chambers is provided, and the cold air generated from the evaporator is provided. Is supplied to the first and second storage chambers through the first and second cooling air ducts by inhaling and blowing air from the blowing fan.

At this time, the first and second cooling air ducts are provided with first and second dampers, respectively, to respectively adjust the amount of cool air supplied to the first and second storage chambers.

When the intake ports of the two storage compartments are conventionally connected to each other, when the blowing fan that sucks the cold air stops, the cold air from the upper storage compartment flows out to the intake port of the lower storage compartment through the intake port of the storage compartment at the top, thereby maintaining the temperature of each storage compartment independently. I had difficulty doing it.

Korean Patent Publication No. 0918443 Korean Patent Publication No. 2014-0004420 Korean Patent Application No. 2013-0041442

The present invention has been conceived to solve the above-described problem, and minimizes the introduction of air sucked through the first inlet into the second storage chamber through the second inlet when the blowing fan for circulating cold air is stopped. ,2 An object of the present invention is to provide a duct assembly and a refrigerator that can more effectively independently maintain the temperature of a storage room.

The duct assembly of the present invention for achieving the above object includes: a first duct for supplying cool air to a first storage compartment, a second duct for supplying cool air to a second storage compartment, and a first duct for sucking air from the first storage compartment. A first suction port, a second suction port for sucking air from the second storage chamber, and a third duct connecting the first suction port and the second suction port, wherein the second suction port is at a lower portion of the first suction port. And a holding space portion for holding at least a portion of the air sucked through the first suction port is formed to communicate with the third duct.

Further, it includes a panel, wherein the first, second, and third ducts and the holding space are formed on the rear surface of the panel, the first suction port is formed on the panel, and the third duct is formed in a vertical direction, The holding space part is disposed under the first suction port, the communication port connecting the second suction port and the third duct is disposed to be alternately with the first suction port, and the holding space part is formed with a horizontal rib formed on the panel and the horizontal It is formed by a second guide rib formed in a direction perpendicular to the rib, a first guide rib is formed surrounding the second duct, and the first suction port is formed between the upper end of the second guide rib and the first guide rib. A gap through which cold air introduced through may flow may be formed.

The refrigerator of the present invention for achieving the above object includes a refrigerator body including a first storage compartment and a second storage compartment, and a duct assembly for supplying cool air to the first storage compartment or the second storage compartment, and the duct assembly A first duct for supplying cool air to the first storage compartment; and a second duct for supplying cool air to the second storage compartment; and a first suction port for sucking air from the first storage compartment; and, the second storage compartment A second suction port for inhaling the air of the first suction port; and a third duct connecting the first suction port and the second suction port; wherein the second suction port is disposed below the first suction port, and the first suction port A holding space portion holding at least a portion of the air sucked through is formed to communicate with the third duct.

The duct assembly may include an evaporator for cooling the first storage compartment and the second storage compartment; and a blower fan for circulating cool air; and a first damper for opening or closing the first duct; and opening the second duct or It may further include a second damper closing.

According to the duct assembly and refrigerator of the present invention as described above, there are the following effects.

It includes a third duct connecting the first inlet and the second inlet, and the holding space portion holding at least a part of the air sucked through the first inlet is formed to communicate with the third duct, and a blowing fan for circulating cold air is provided. When the air is stopped, it is possible to more effectively independently maintain the temperature of the first and second storage chambers by minimizing the air inhaled through the first inlet and entering the second storage chamber through the second inlet.

A panel, wherein the first, second, and third ducts and the holding space are formed on the rear surface of the panel, the first suction port is formed on the panel, and the third duct is formed in a vertical direction, and the holding The space portion is disposed under the first suction port, and when the blower fan is operated, the air sucked from the first and second storage chambers can be smoothly merged and circulated smoothly.

1 is a schematic cross-sectional side view of a refrigerator body according to a preferred embodiment of the present invention.
2 is a rear perspective view showing a state in which the rear panel is separated from the refrigerator duct assembly according to an exemplary embodiment of the present invention.
3 is a perspective view showing a state in which the front panel and the bracket panel of the duct assembly of FIG. 2 are separated.
Figure 4 is a front view of the duct assembly of Figure 2;
Figure 5 is a perspective view of the rear panel of the duct assembly of Figure 2;
6 is a perspective view of the duct assembly of FIG. 2 viewed from the bottom.
Figure 7 is a perspective view of the rear coupling of the duct assembly of Figure 2;
Figure 8 is a front view of the blower fan and the rear panel of the duct assembly of Figure 2;

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

For reference, among the configurations of the present invention to be described below, the above-described conventional technology will be referred to for the same configuration as the prior art, and a separate detailed description will be omitted.

As shown in FIGS. 1 to 8, the refrigerator according to the present embodiment includes a refrigerator main body 100 including a first storage compartment 110 and a second storage compartment 120, and the first storage compartment 110 or the first storage compartment 110. 2 A duct assembly for supplying cool air to the storage compartment 120, wherein the duct assembly includes a first duct 206 for supplying cool air to the first storage compartment 110; and, cold air to the second storage compartment 120 A second duct (207) for supplying a; and, a first inlet 203 for inhaling air of the first storage chamber 110; and a second inlet 214 for inhaling air of the second storage chamber 120 ); and, a third duct 208 connecting the first suction port 203 and the second suction port 214; and the second suction port 214 is a lower portion of the first suction port 203 A holding space portion 228 disposed in and holding at least a part of the air sucked through the first suction port 203 is formed to communicate with the third duct 208.

The refrigerator body 100 includes a first storage compartment 110 and a second storage compartment 120 separated from the first storage compartment 110. The refrigerator body 100 is formed such that the front surface thereof is open including the side surface and the bottom surface, and the upper surface and the rear surface 101.

The second storage compartment 120 may be disposed under the first storage compartment 110.

Separation plates 130 are disposed horizontally between the first storage compartment 110 and the second storage compartment 120 so that the first storage compartment 110 and the second storage compartment 120 can be maintained at separate temperatures, so that the two spaces are separated. do.

The refrigerator body 100 is provided with an input unit (such as a button or a touch panel) capable of separately changing the mode (freezing, refrigerating, fresh freezing, kimchi storage mode, etc.) of each storage room on a door or the like. Therefore, each storage chamber of this embodiment can be independently maintained at different temperatures.

The first storage compartment 110 and the second storage compartment 120 may be opened or closed by a single door (not shown) or may be individually opened or closed by providing individual doors.

The evaporator (not shown) cools the first storage chamber 110 and the second storage chamber 120 by an intercooling method. That is, the evaporator cools two or more storage chambers with one evaporator.

The refrigerator of the present embodiment further includes a duct assembly for supplying cold air to the first storage compartment 110 or the second storage compartment 120. The duct assembly may be installed in front of the rear surface 101 of the refrigerator body 100.

The duct assembly includes a first duct 206 connected to the first storage chamber 110 to supply cool air to the first storage chamber 110, a first damper 240 for opening or closing the first duct 206, A second duct 207 connected to the second storage room 120 to supply cold air to the second storage room 120, a second damper 260 opening or closing the second duct 207, and the evaporator. And a blower fan 250 for transferring the cooled air (cold air) to the first duct 206 or the second duct 207 and circulating the cool air. One blowing fan 250 supplies cool air through the first duct 206 and the second duct 207 to cool the first storage chamber 110 and the second storage chamber 120.

The duct assembly includes a front panel including a first front panel 210 and a second front panel 220 disposed behind the first front panel 210, and a front panel disposed behind the second front panel 220. It includes a plate-shaped panel including the rear panel 230. In the present embodiment, the panel is composed of three panels, but differently, the panel may be formed to include only one plate-shaped panel.

The first duct 206 and the second duct 207 are integrally formed on one panel. Therefore, installation of the duct can be made easy and quick, and the manufacturing cost can be reduced.

The second front panel 220 is installed by being fitted to the rear of the first front panel 210.

In the first front panel 210 and the second front panel 220, a first discharge port 201 for discharging cool air to the first storage compartment 110 is formed at the top, and is disposed under the first storage compartment 110. First intake ports 203 for inhaling air from the first storage chamber 110 are formed on both sides of the lower side of the first discharge port 201, and in the second storage chamber 120 at the bottom between the first intake ports 203 on both sides. A second discharge port 202 for discharging cold air is formed, and a second suction port 214 for inhaling air from the second storage compartment 120 so as to be disposed under the second storage compartment 120 under the second discharge port 202 ) Is formed.

The first suction port 203 is disposed above the separating plate 130.

Two second discharge ports 202 are formed, and the two second discharge ports 202 are disposed in the vertical direction so as to be disposed in the upper and middle portions of the second storage chamber 120.

The first front panel 210 is formed in a plate shape, and first sidewalls 212 surrounding both sides and upper edges are formed.

A fastening member 211 is formed on the first side wall 212 so that the duct assembly is installed on the inner wall of the refrigerator body 100. The fastening member 211 is formed with a protruding hook.

The fastening members 211 are disposed on the upper, side, and lower portions of the first front panel 210, respectively.

In addition, a fastening hole 213 for coupling the first front panel 210 and the rear panel 230 is formed in the first side wall 212. The fastening holes 213 are disposed only on both sides of the first front panel 210.

The fastening member 211 and the fastening hole 213 are alternately arranged.

A guide protrusion 215 surrounding the second discharge port 202 is formed in front of the first front panel 210.

Further, in front of the first front panel 210, temperature sensor seating grooves 216 disposed in the first storage chamber 110 and the second storage chamber 120 are formed. A cutout is formed on one side of the temperature sensor seating groove 216 so that a wire or the like can be easily drawn between the first front panel 210 and the second front panel 220. Therefore, it is possible to protect the electric device by preventing the electric wire from coming into contact with cold air.

A second suction port 214 is formed under the first front panel 210 in a grill shape.

The second front panel 220 is also formed in a plate shape.

The second front panel 220 may be formed of a styrofoam material to provide an insulating effect.

The first damper 240 is disposed under the first discharge port 201.

A seating groove 229 is formed on the rear surface of the second front panel 220 so that the second damper 260 is installed and seated.

The second damper 260 is disposed above the second discharge port 202.

A first duct 206, a second duct 207, and a third duct 208 are formed on the rear surface of the second front panel 220. The rear surface (at least one side) of each duct is opened, and the rear surface of the opened duct is surrounded by a rear panel 230.

The first duct 206 is formed between the first discharge port 201 and the first damper 240.

The second duct 207 is formed between the second damper 260 and the second discharge port 202.

A first guide rib 223 is disposed between the second front panel 220 and the rear panel 230 of the front panel.

The first guide drive 223 is disposed between the first suction port 203 and the second discharge port 202 to form an independent flow path to mix the cold air of the first storage compartment 110 and the second storage compartment 120 It will not be. Accordingly, the temperature of the first storage chamber 110 and the second storage chamber 120 can be independently and effectively maintained.

A first guide rib 223 surrounding the second duct 207 is formed to protrude from the rear surface of the second front panel 220. A tapered portion having a narrow gap between both sides of the first guide rib 223 is formed, and the tapered portion is disposed under the second discharge port 202 disposed below. Water formed in the second duct 207 by the tapered portion may be effectively collected under the second duct 207. In this way, the duct is formed by ribs or the like protruding from the flat surface of the panel.

The third duct 208 is formed in the vertical direction between the first suction port 203 and the second suction port 214. The third duct 208 communicates with the first suction port 203 and the second suction port 214, respectively, and connects the first suction port 203 and the second suction port 214. The third duct 208 is formed on both sides of the first guide rib 223, respectively. Accordingly, the second duct 207 and the third duct 208 are separated by the first guide rib 223.

A horizontal rib and a second guide rib 224 formed in a vertical direction above one side of the horizontal rib are protruded on both sides of the lower side of the rear surface of the second front panel 220 to form a holding space portion 228. The upper end of the second guide drive 224 is spaced apart from the lower end of the first guide drive 223 to form a gap. The cold air introduced through the first suction port may flow through the gap. The air sucked through the first inlet 203 passes between the first guide rib 223 and the second guide rib 224 and is guided through both second guide ribs 224 to be guided through the second inlet port 214 and the middle upper part ( 204). The cold air goes down, and the second suction port 214 joined thereto is disposed under the first suction port 203 to facilitate circulation of the cool air. In addition, it is possible to simplify the cold air flow path and minimize the load received by the flowing air.

The second guide rib 224 is disposed to be spaced apart from the second side wall 225 of the second front panel 220 so that the holding space portion 228 is formed between the second guide rib 224 and the second side wall 225. Is formed. Accordingly, the holding space portion 228 is formed to communicate with the third duct 208 between the first suction port 203 and the second suction port 214.

The holding space part 228 is disposed under the first suction port 203.

The communication port connecting the second suction port 214 and the third duct 208 is disposed in the center and is disposed to be alternately with the first suction port 203.

Due to this holding space portion 228, at least a portion of the air sucked through the first suction port 203 is held in the holding space portion 228. Accordingly, when the blowing fan 250 is stopped, it is possible to prevent the air introduced through the first suction port 203 from being directly discharged to the second suction port 214. That is, when the blowing fan 250 is stopped, it is possible to minimize the cold air from the first storage compartment 110 from flowing into the second storage compartment 120. Therefore, the temperature of each storage chamber can be maintained independently.

The left and right widths of the second front panel 220 are formed to be smaller than the distance between the first side walls 212 on both sides of the first front panel 210. Accordingly, a space portion 205 is formed between the second side walls 225 and the first side walls 212 of the second front panel 220.

The rear panel 230 is formed in a plate shape, and the third side walls 231 are formed at both edges to protrude forward and rearward. The rear panel 230 is formed such that the inner wall 239 protrudes forward so that the rear panel 230 is disposed to be spaced apart from the third side wall 231.

The lower ends of the second front panel 220 and the rear panel 230 are disposed above the second suction port 214.

The third side wall 231 has a fastening portion 233 inserted into the fastening hole 213 to protrude in a hook shape.

The inner wall 239 may be inserted into the space 205 so that the assembly of the duct assembly may be solid.

In front of the rear panel 230, a casing portion 238 surrounding the blowing fan 250 along the circumferential direction is formed to protrude in a plate shape. In this way, a casing 238 surrounding a side edge of the blowing fan 250 is formed in front of the rear panel 230 to form a blowing fan seating groove in which the blowing fan 250 is seated. A blowing fan fastening part is formed on the rear panel 230 so that the blowing fan 250 can be installed to be disposed outside the casing 238.

As shown in FIG. 8, a first cold air outlet 238a for supplying cold air to the first storage chamber 110 is formed in the casing unit 238, and a second storage chamber 238a spaced apart from the first cold air outlet 238a ( A second cold air discharge port 238b for supplying cold air to 120 is formed.

The first cold air outlet 238a is disposed above the second cold air outlet 238b. In detail, the first cold air outlet 238a is disposed above the blowing fan 250 and the second cold air outlet 238b is disposed below the blowing fan 250. Accordingly, the casing portions 238 are disposed on both sides of the blowing fan 250, respectively.

The first cool air discharge port 238a and the second cool air discharge port 238b are disposed so that the centers of the first cool air discharge port 238a and the second cool air discharge port 238b are alternately formed. Specifically, when the blowing fan 250 rotates in a counterclockwise direction, the center of the first cold air outlet 238a is disposed to the left of the center of the second cold air outlet 238b. This arrangement structure may vary depending on the rotation direction of the blowing fan 250.

The casing portion 238 has a first space portion 238c' formed on the surface (left side) of the surfaces disposed on both sides of the first cold air outlet 238a that faces the air blown when the blowing fan 250 operates. The first enlarged bent portion 238c is formed so as to be. The first expanding bent portion 238c is disposed to be close to the first cold air discharge port 238a. The first expanding bent portion 238c is disposed on the left side of the inlet of the first cold air discharge port 238a.

A portion of the casing portion 238 where the portion 238d connected to the first enlarged bent portion 238c abuts is formed in a curved surface.

The first diaphragm bent portion 238c has a larger diameter toward the upper first cold air discharge port 238a. The first enlarged bent portion 238c may be 3 to 3.1 times the diameter of the blowing fan 250.

Preferably, the central angle (b) of the first widening bent portion 238c is set to be 25 degrees to 25.5 degrees, so that the reverse flow of cold air can be further minimized.

It is preferable that the angle (a) from the center line of the blowing fan 250 to the upper end of the first enlarged bent portion 238c is 27 degrees to 27.5 degrees.

The portion 238d connected to the lower end of the first widening bent portion 238c in the casing 238 is the distance between the end of the blowing fan 250 as it goes toward the second cold air outlet 238b (toward the bottom) It is formed so that the (radiation direction) is widened.

The casing portion 238 has a second space portion 238f' formed on the surface (right side) of the surfaces disposed on both sides of the second cold air outlet 238b that faces the air blown when the blowing fan 250 operates. The second diffusing bent portion 238f is formed so as to be. The second expanding bent portion 238f is disposed to be close to the second cold air discharge port 238b. The second enlarged bent portion 238f is disposed on the right side of the inlet of the second cold air discharge port 238b.

When the cold air is discharged to the first and second cold air outlets 238a and 238b due to the first and second widening bent portions 238a and 238f, the reverse flow of cold air is minimized.

The portion 238e connected to the upper end of the second widening bent portion 238f from the casing 238 has a wider gap with the blowing fan 250 as it goes toward the first cold air outlet 238a (toward the top). It is formed to lose. A portion where the portion 238e connected to the second amplifying bent portion 238f abuts is formed in a curved surface.

Accordingly, cold air can be more smoothly discharged through the first cold air outlet 238a and the second cold air outlet 238b.

A suction hole 235 is formed through the rear panel 230 so as to be disposed inside the casing 238 surrounding the blowing fan 250.

The diameter of the suction hole 235 is preferably 0.7 to 0.73 times the diameter of the blowing fan 250.

In addition, a portion 238g of the rear panel 230 disposed at the rear of the blower fan 250 is formed to be bent (in a shape of a sphere) to protrude rearward. This can make the circulation of cold air more smooth.

In addition, insertion grooves 236 into which the first and second guide ribs 223 and 224 are inserted are formed in front of the rear panel 230. In addition, mixing of the cold air in the first and second storage chambers 110 and 120 due to the insertion groove 236 is more effectively prevented.

A damper seating groove 234 in which the first and second dampers 240 and 260 are seated is formed in front of the rear panel 230. In front of the rear panel 230, a first damper 240, a blower fan 250, and a second damper 260 are sequentially installed from the top. That is, the blowing fan 250 is disposed between the first damper 240 and the second damper 260.

Assembly is facilitated by the insertion groove 236 and the damper seating groove 234.

Further, a drain hole 237 is formed in the rear panel 230 to communicate with the second duct 207 and the third duct 208. Water formed in each duct may be discharged through the drain hole 237.

A fourth duct 209 is formed on the rear surface of the rear panel 230 due to a third side wall 231 protruding rearward and a separation wall 232 disposed in the middle and upper portions of the blowing fan 250. The fourth duct 209 raises the air sucked through the first suction port 203 and the second suction port 214 to the top and supplies it to the blowing fan 250.

The rear, which is an open portion of the fourth duct 209, is surrounded by the rear surface 101 of the refrigerator body 100.

The cross-sectional area of the fourth duct 209 for supplying the inhaled air is formed to be wide, so that the circulation of air may be more smooth. In addition, cooling efficiency can be maximized by transporting the intake air, which has increased temperature, between the rear side of the duct assembly and the rear side 101 of the refrigerator body 100 to be spaced apart from the first and second storage chambers 110 and 120 as much as possible.

The evaporator is disposed inside the fourth duct 209. Accordingly, the evaporator is disposed between the rear panel 230 and the rear surface 101 of the refrigerator body 100. That is, the evaporator is disposed under the rear surface of the rear panel 230.

The suction air transferred through the fourth duct 209 passes through the suction hole 235 and is supplied to the blowing fan 250.

Since the detailed structure and illustration of the damper is shown in the prior art, a detailed description thereof will be omitted.

The control unit constantly supplies cold air to the storage compartment having a lower target temperature among the first storage compartment 110 and the second storage compartment 120.

In detail, the control unit controls the first damper 240 and the second damper 260 to constantly supply cold air to the storage compartment having a lower target temperature among the first storage compartment 110 and the second storage compartment 120. I can.

For example, when the user changes the mode to lower the target temperature (-4°C) of the first storage compartment 110 through the input unit or the like to be lower than the target temperature (3°C) of the second storage compartment 120, the controller The first damper 240 may be in an open state at all times so that the first duct 206 may be in an open state so that cold air is continuously discharged through the first duct 206. In addition, the control unit opens or closes the second duct 207 by opening or closing the second damper 260 connected to the second storage chamber 120 having a higher target temperature according to a temperature activation condition.

The temperature starting condition means that when the temperature value detected by the temperature sensor that detects the temperature of each storage room is higher than the target temperature, the corresponding duct connected to the storage room is opened, and when the detected temperature value reaches the target temperature, the corresponding duct is closed. .

Hereinafter, a method for controlling a refrigerator according to the present embodiment having the above-described configuration will be described.

The refrigerator control method of the present embodiment includes determining a storage compartment having a lower target temperature among the first storage compartment and the second storage compartment 120 cooled through the same evaporator as the first storage compartment 110, and a lower target temperature. It includes a control step of supplying cold air at all times to the storage room having a.

In the determining step, the controller determines a storage room having a lower target temperature by comparing target temperatures of each storage room according to a mode input through the input unit or the like.

In the control step, the control unit controls the first damper 240 installed in the first duct 206 connected to the first storage chamber 110 having a lower target temperature to an open state at all times, so that it is always in the first storage chamber 110. To supply cold air.

In addition, the controller opens or closes the second damper 260 to open or close the second duct 207 connected to the second storage chamber 120 having a higher target temperature according to a temperature start condition.

Accordingly, the refrigerant flow path can be simplified and the number of parts can be reduced, and at the same time, each storage room can be converted into various modes such as refrigeration, refrigeration, and kimchi storage mode, and the temperature of each storage room can be effectively maintained.

As described above, although it has been described with reference to a preferred embodiment of the present invention, those skilled in the art will variously modify or modify the present invention within the scope not departing from the spirit and scope of the present invention described in the following claims. It can be done.

** Description of symbols for major parts of the drawing **
100: refrigerator body 110: first storage room
120: second storage room 130: separation wall
240: first damper 260: second damper
206: first duct 207: second duct

Claims (7)

A first duct for supplying cold air to the first storage compartment;
A second duct for supplying cold air to the second storage compartment;
A first suction port for sucking air from the first storage chamber;
A second suction port for sucking air from the second storage chamber;
Includes; a third duct connecting the first suction port and the second suction port,
The second suction port is disposed below the first suction port,
The holding space portion holding at least a portion of the air sucked through the first inlet is formed to communicate with the third duct,
The third duct is formed in the vertical direction,
The holding space portion is disposed under the first suction port,
The communication port connecting the second suction port and the third duct is a duct assembly disposed to be staggered with the first suction port. The method of claim 1,
Including panels,
The first, second, and third ducts and the holding space are formed on the rear surface of the panel,
The first suction port is a duct assembly formed in the panel. delete The method of claim 2,
The holding space portion is a duct assembly formed by a horizontal rib formed on the panel and a second guide rib formed in a direction perpendicular to the horizontal rib. The method of claim 4,
A first guide rib is formed surrounding the second duct,
A duct assembly in which a gap through which cold air introduced through the first inlet can flow is formed between an upper end of the second guide drive and the first guide drive. A refrigerator main body including a first storage compartment and a second storage compartment;
And a duct assembly for supplying cold air to the first storage compartment or the second storage compartment,
The duct assembly includes: a first duct for supplying cool air to the first storage compartment; and a second duct for supplying cool air to the second storage compartment; and a first inlet for sucking air from the first storage compartment; and, the A second inlet for inhaling air from the second storage chamber; and a third duct connecting the first inlet and the second inlet, wherein the second inlet is disposed below the first inlet, and the The holding space portion for holding at least a portion of the air sucked through the first inlet is formed to communicate with the third duct,
The third duct is formed in the vertical direction,
The holding space portion is disposed under the first suction port,
The communication port connecting the second suction port and the third duct is disposed to be alternately disposed with the first suction port. The method of claim 6,
The duct assembly may include an evaporator for cooling the first storage compartment and the second storage compartment; and a blower fan for circulating cool air; and a first damper for opening or closing the first duct; and opening the second duct or The refrigerator further comprising a second damper closing.

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