KR20160023125A - The control method of refrigerator and refrigerator - Google Patents

Abstract

The present invention relates to a control method for a refrigerator and a refrigerator and, more specifically, relates to a refrigerator which can more freshly store fresh food such as kimchi while simplifying a refrigerant flow path and reducing the number of components by preferentially supplying cooling air to a storage chamber which is in a kimchi storage mode of a first storage chamber and a second storage chamber cooled through the same evaporator with the first storage chamber.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a refrigerator,

The present invention relates to a refrigerator control method and a refrigerator, and more particularly, to a refrigerator that first supplies cold air to a storage room, which is a kimchi storage mode, among a first storage room and a second storage room that is cooled through the same evaporator as the first storage room will be.

Generally, a refrigerator or a Kimchi refrigerator (hereinafter referred to as a refrigerator) constitutes a refrigeration cycle with a compressor, a condenser, an expansion device, and an evaporator as main components, and a heater It is a device for storing the stored material stored in the storage room through heat transfer, in an aged or low temperature state as necessary.

The refrigerator has a direct cooling type in which a storage room is cooled by using a pipe type evaporator arranged to surround an outer surface of the storage space according to a cooling system, an evaporator having a cooling fin at one side of the storage room and a blowing fan, And an indirect cooling method in which cold air is supplied to the storage room through the cooling air flow path by driving. Meanwhile, in recent years, a hybrid refrigerator has been proposed in which a direct cooling type storage room and a hepatic cooling type storage room are mixedly applied.

As shown in Korean Patent Laid-Open Publication No. 2014-0004420, when two or more indirect storage type storage rooms are formed, each of the first and second storage rooms is provided with a cold air duct for supplying cold air, Is sucked and blown by a blowing fan and supplied to the first and second storage rooms through the first and second cool air ducts, respectively.

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

Such a conventional refrigerator turns on and off the damper according to the individual room temperature start condition irrespective of the mode of each storage room. Therefore, there is a problem in that each storage room can not effectively maintain the temperature desired by the user.

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

The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to provide a refrigerator and a refrigerator which can simplify a refrigerant passage and reduce the number of parts, effectively maintain the temperature of each storage room, A refrigerator control method is provided.

According to another aspect of the present invention, there is provided a method of controlling a refrigerator comprising the steps of: determining a storage room, which is a kimchi storage mode, among a first storage room and a second storage room that is cooled through the same evaporator as the first storage room; And a control step of preferentially supplying cool air to the storage chamber.

The control step controls the damper installed in the duct connected to each storage room to preferentially supply cool air to the storage room in the kimchi storage mode. In the control step, cool air is supplied only to the storage room in the kimchi storage mode, The cool air is not supplied to the first storage chamber and the second storage chamber when the temperature of the storage chamber, which is the kimchi storage mode, becomes the kimchi storage temperature.

According to an aspect of the present invention, there is provided a refrigerator including a refrigerator body including a first storage chamber and a second storage chamber, an evaporator for cooling the first storage chamber and the second storage chamber, And a control unit for preferentially supplying cool air to the storage room in the storage room, which is the kimchi storage mode.

A first duct connected to the first storage chamber for supplying cool air to the first storage chamber, a first damper for opening and closing the first duct, and a second damper connected to the second storage chamber to supply cool air to the second storage chamber And a second damper that opens or closes the second duct, wherein the controller controls an angle of the first damper and the second damper to store the kimchi in the first storage room and the second storage room Cool air is preferentially supplied to the storage room, which is a mode.

According to the refrigerator and refrigerator control method of the present invention as described above, the following effects can be obtained.

The cool air is preferentially supplied to the storage room which is the kimchi storage mode out of the first storage room and the second storage room which is cooled through the same evaporator as the first storage room so as to simplify the refrigerant flow path and reduce the number of parts, While preserving fresh food such as kimchi, which is more sensitive to temperature, more freshly.

Wherein the control step is to supply cool air only to the storage room which is the kimchi storage mode, and not to supply the cool air to the storage room other than the kimchi storage mode, and in the control step, when the temperature of the storage room which is the kimchi storage mode becomes the kimchi storage temperature, And the fresh food can be stored more effectively by supplying cold air alternately to the second storage room.

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

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

For reference, the same components as those of the conventional art will be described with reference to the above-described prior art, and a detailed description thereof will be omitted.

1 to 8, the refrigerator of the present embodiment includes a refrigerator main body 100 including a first storage room 110 and a second storage room 120, a refrigerator main body 100 including the first storage room 110 and the second storage room 120, And a controller (not shown) for preferentially supplying cool air to the storage room, which is a kimchi storage mode, of the first storage room 110 and the second storage room 120 do.

The refrigerator body 100 includes a first storage room 110 and a second storage room 120 separated from the first storage room 110. The refrigerator body 100 is formed to have a front surface including side surfaces, a bottom surface, an upper surface and a rear surface 101.

The second storage chamber 120 may be disposed below the first storage chamber 110.

A separation plate 130 is horizontally disposed between the first storage chamber 110 and the second storage chamber 120 so as to maintain the first storage chamber 110 and the second storage chamber 120 at independent temperatures, do.

The refrigerator body 100 is provided with an input unit (a button, a touch panel, or the like) capable of separately changing modes (refrigeration, refrigeration, liveliness, kimchi storage mode, etc.) of each storage room on a door or the like. Thus, each storage chamber of the present embodiment can be independently maintained at different temperatures.

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

The evaporator (not shown) cools the first storage compartment 110 and the second storage compartment 120 by an indirect cooling method. That is, the evaporator cools two or more storage compartments with one evaporator.

The refrigerator of the present embodiment further includes a duct assembly for supplying cool air to the first storage chamber 110 or the second storage chamber 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 and supplying cool air to the first storage chamber 110, a first damper 240 opening and closing the first duct 206, A second duct 207 connected to the second storage chamber 120 to supply cool air to the second storage chamber 120, a second damper 260 for opening or closing the second duct 207, And a blowing fan 250 that conveys the cooled air (cool air) to the first duct 206 or the second duct 207 and circulates the cool air. Cooling air is supplied through the first duct 206 and the second duct 207 to the first storage chamber 110 and the second storage chamber 120 by a single blowing fan 250.

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 rear panel 220 disposed behind the second front panel 220 And a rear panel (230). In the present embodiment, the panel is formed of three panels. Alternatively, the panel may be formed to include only one panel.

The first duct 206 and the second duct 207 are integrally formed on one panel. Therefore, the duct can be installed easily and quickly, and the manufacturing cost can be reduced.

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

The first discharge panel 201 and the second front panel 220 are formed with a first discharge port 201 for discharging cold air into the first storage compartment 110 and a second discharge port 201 disposed below the first storage compartment 110 A first suction port 203 for sucking air in the first storage chamber 110 is formed on both sides of the lower portion of the first discharge port 201 and a second suction port 203 for sucking air in the second storage chamber 120 is provided below the first suction ports 203 on both sides. A second suction port 214 for sucking air in the second storage chamber 120 so as to be disposed below the second storage chamber 120 at a lower portion of the second discharge port 202; Is formed.

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

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

The first front panel 210 is formed in a plate shape, and a first side wall 212 is formed to surround both sides and the upper edge.

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 as a protruding hook.

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

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

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

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

A temperature sensor seating groove 216 is formed in front of the first front panel 210 and is disposed in the first storage chamber 110 and the second storage chamber 120, respectively. The temperature sensor seating groove 216 is formed with a cutout at one side thereof to easily draw electric wires and the like between the first front panel 210 and the second front panel 220. Therefore, the electric wire can be prevented from coming into contact with the cold air, so that the electric device can be protected.

A second suction port 214 is formed in the lower part of 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 a thermal insulation effect.

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

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

The second damper 260 is disposed on the upper portion of 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 surface) of each duct is opened, and the rear surface of the opened duct is surrounded by the 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 rib 223 is disposed between the first suction hole 203 and the second discharge hole 202 to form an independent flow path so that the first and second guide ribs 223 and 223 mix the cold air of the first storage chamber 110 and the second storage chamber 120 . Therefore, the temperatures of the first storage chamber 110 and the second storage chamber 120 can be maintained independently and effectively.

A first guide rib 223 surrounding the second duct 207 protrudes from the rear of the second front panel 220. A tapered portion is formed at a lower portion of the first guide rib 223 to narrow the gap between the both sides. The tapered portion is disposed below the second discharge port 202 disposed at the lower portion. The water formed inside the second duct 207 can be efficiently collected under the second duct 207 by the tapered portion. Thus, the duct is formed by a rib or the like protruding from the flat surface of the panel.

The third duct 208 is vertically formed 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 to connect the first suction port 203 and the second suction port 214, respectively. The third duct 208 is formed on both sides of the first guide rib 223, respectively. Therefore, the second duct 207 and the third duct 208 are separated by the first guide ribs 223.

A lateral rib and a second guide rib 224 formed in a vertical direction on one side of the lateral rib are protruded from 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 rib 224 is spaced apart from the lower end of the first guide rib 223 to form a gap. The cool air introduced through the first inlet may flow through the gap. The air sucked into the first suction port 203 passes between the first guide ribs 223 and the second guide ribs 224 and is guided through both the second guide ribs 224 so that the intermediate upper portion of the second suction port 214 204, respectively. The cold air is moved downward and the second suction port 214 merged is disposed below the first suction port 203 so that circulation of the cold air can be smoothly performed. Further, the cooling air flow path can be simplified, and the load on the air to be flowed can be minimized.

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

The holding space portion 228 is disposed at a lower portion of the first suction port 203.

The communication port for connecting the second suction port 214 and the third duct 208 is disposed at the center portion and is arranged to be staggered with the first suction port 203.

Due to this retention space portion 228, at least a part of the air sucked through the first suction port 203 is retained in the retention space portion 228. Therefore, when the blowing fan 250 is stopped, the air introduced through the first suction port 203 can be prevented from being directly discharged to the second suction port 214. That is, it is possible to minimize the inflow of the cool air of the first storage chamber 110 into the second storage chamber 120 when the blowing fan 250 is stopped. Therefore, the temperature of each storage chamber can be maintained independently.

The width of the second front panel 220 is smaller than the distance between the first side walls 212 of the first front panel 210. Therefore, a space portion 205 is formed between the second sidewall 225 and the first sidewall 212 of the second front panel 220.

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

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

The third side wall 231 is formed with a coupling part 233 inserted into the coupling hole 213 protruding in the form of a hook.

The inner wall 239 is inserted into the space portion 205 so that the assembly of the duct assembly can be rigid.

A casing portion 238 surrounding the ventilation fan 250 in the circumferential direction is formed in a plate shape in front of the rear panel 230. In this way, a casing 238 surrounding the side edge of the blowing fan 250 is formed in front of the rear panel 230 to form a blowing fan mounting groove on 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 so as to be disposed outside the casing 238.

8, a first cooling air discharge opening 238a for supplying cool air to the first storage chamber 110 is formed in the casing portion 238 and a second cooling air discharge opening 238b is formed in the second storage chamber 238a so as to be spaced apart from the first cooling air discharge opening 238a. The second cold air discharge port 238b for supplying the cold air to the second air discharge port 238b.

The first cool air discharge port 238a is disposed above the second cool air discharge port 238b. Specifically, the first cooling air discharge opening 238a is disposed above the air blowing fan 250 and the second air discharge opening 238b is disposed below the air cooling fan. Therefore, the casing portion 238 is disposed on both sides of the blowing fan 250, respectively.

The first cold air discharge port 238a and the second cold air discharge port 238b are arranged so that their centers are staggered from each other. Specifically, when the blowing fan 250 rotates counterclockwise, the center of the first air discharge opening 238a is disposed on the left side of the center of the second air discharge opening 238b. This arrangement may vary depending on the direction of rotation of the blowing fan 250.

A first space portion 238c 'is formed on the surface (left side) facing the air blown when the blowing fan 250 is operated among the surfaces disposed on both sides of the first cooling air discharge opening 238a in the casing portion 238 The first bending portion 238c is formed. The first bending portion 238c is arranged close to the first air discharge opening 238a. The first bending portion 238c is disposed on the left side of the inlet of the first air discharge opening 238a.

The portion of the casing portion 238 where the portion 238d connected to the first large-diameter bent portion 238c abuts is formed as a curved surface.

The diameter of the first large diameter bent portion 238c becomes larger toward the upper first cool air discharge port 238a. The first diameter bending portion 238c may be three to three times the diameter of the blowing fan 250. [

Preferably, the central angle b of the first bending portion 238c is 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 diameter bending portion 238c is 27 degrees to 27.5 degrees.

The portion 238d connected to the lower end of the first bending portion 238c in the casing portion 238 is spaced from the end of the blowing fan 250 toward the second air discharge opening 238b (Radial direction) is widened.

A second space 238f 'is formed in the casing portion 238 on the side (right side) facing the air blown when the blowing fan 250 operates, of the surfaces disposed on both sides of the second air discharge opening 238b The second bending portion 238f is formed. And the second bending portion 238f is disposed so as to be close to the second air discharge opening 238b. The second bending portion 238f is disposed on the right side of the inlet of the second air discharge opening 238b.

The first and second large diameter bending portions 238a and 238f minimize the backflow of cold air released from the cold air discharge to the first and second air discharge openings 238a and 238b.

The portion 238e connected to the upper end of the second bending portion 238f in the casing portion 238 has a larger distance from the blowing fan 250 toward the first air discharge opening 238a . The portion where the portion 238e connected to the second bending portion 238f abuts is formed as a curved surface.

As a result, the cool air can be discharged more smoothly to the first cold air discharge opening 238a and the second cold air discharge opening 238b.

A suction hole 235 is formed in the rear panel 230 so as to be disposed inside a casing portion 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.

Further, a portion 238g disposed on the rear side of the blowing fan 250 in the rear panel 230 is formed to bend (partially spherical) so as to protrude rearward. As a result, the circulation of cool air can be made more smooth.

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

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

The insertion groove 236 and the damper seating groove 234 facilitate assembly.

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 can be discharged through the drain hole 237.

The fourth duct 209 is formed on the rear surface of the rear panel 230 by the third side wall 231 protruding rearward and the partition wall 232 disposed in the middle and upper portion of the ventilation fan 250. The fourth duct 209 raises the air sucked through the first suction port 203 and the second suction port 214 upward to supply the air to the blowing fan 250.

The rear portion, 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 sucked air is formed to be wide, so that circulation of the air can be made more smooth. In addition, the increased intake air can be transferred between the rear of the duct assembly and the rear surface 101 of the refrigerator body 100 to maximize the cooling efficiency by maximally separating the intake air from the first and second storage rooms 110 and 120.

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 on the lower rear surface of the rear panel 230.

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

The detailed structure and the structure of such a damper are shown in the related art and the like, and a detailed description thereof will be omitted.

The controller preferentially supplies the cool air to the storage room of the first storage room 110 and the second storage room 120, which is a kimchi storage mode.

Specifically, the controller controls the first damper 210 and the second damper 220 to preferentially supply cool air to the storage room of the first storage room 110 and the second storage room 120, which is a kimchi storage mode.

For example, when the user sets the first storage room 110 to the kimchi storage mode and the second storage room 120 to the mode other than the kimchi storage mode through the input unit or the like, the controller controls the first damper 210 The first duct 230 is always opened so that the cold air can be continuously discharged through the first duct 230. In addition, the control unit closes the second damper 220 connected to the second storage room 120, which is a mode other than the kimchi storage mode, and closes the second duct 240 so that cool air is not supplied to the storage room other than the kimchi storage mode.

The controller may alternately open the first damper 210 and the second damper 220 when the temperature of the storage room (sensed through a temperature sensor or the like), which is the kimchi storage mode, reaches the kimchi storage temperature, 110 and the second storage compartment 120 alternately.

Hereinafter, the refrigerator control method of the present embodiment having the above-described configuration will be described.

The method of controlling a refrigerator of the present embodiment includes the steps of determining a storage room in a kimchi storage mode among a first storage room 110 and a second storage room 120 cooled through the same evaporator as the first storage room 110, And a control step of preferentially supplying cold air to the storage room.

In the determining, the controller determines whether each storage room is in the kimchi storage mode according to the mode input through the input unit or the like.

In the control step, the controller opens the first damper 210 to supply cool air only to the first storage room 110, which is the kimchi storage mode, and the second storage room 120, which is not the kimchi storage mode, The damper 220 is closed and no cold air is supplied.

The control unit alternately supplies cool air to the first storage room 110 and the second storage room 120 when the temperature of the first storage room 110, which is the kimchi storage mode, reaches the kimchi storage temperature (target temperature).

This makes it possible to store kimchi which is particularly sensitive to temperature more freshly, simplify the refrigerant channel and reduce the number of parts, and at the same time, convert each storage room into various modes such as refrigeration, refrigeration, The temperature of the storage chamber can be effectively maintained.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims .

DESCRIPTION OF REFERENCE NUMERALS
100: refrigerator main body 110: first storage room
120: second storage room 130: separating wall
210: first damper 220: second damper
230: first duct 240: second duct

Claims (6)

A first storage room and a second storage room that is cooled through the same evaporator as the first storage room;
And a control step of preferentially supplying cool air to the storage room, which is a kimchi storage mode. The method according to claim 1,
Wherein the controlling step controls a damper installed in a duct connected to each storage room to preferentially supply cool air to a storage room in a kimchi storage mode. 3. The method according to claim 1 or 2,
Wherein the control step supplies cool air only to the storage room which is the kimchi storage mode and does not supply cool air to the storage room which is not the kimchi storage mode. 3. The method of claim 2,
The control step
When the temperature of the storage room, which is the kimchi storage mode, becomes the kimchi storage temperature,
And the cool air is alternately supplied to the first storage room and the second storage room. A refrigerator body including a first storage room and a second storage room;
An evaporator for cooling the first storage chamber and the second storage chamber;
And a controller for preferentially supplying cool air to the storage room of the kimchi storage mode among the first storage room and the second storage room. 6. The method of claim 5,
A first duct connected to the first storage chamber and supplying cool air to the first storage chamber;
A first damper that opens or closes the first duct;
A second duct connected to the second storage room to supply cool air to the second storage room;
And a second damper for opening or closing the second duct,
Wherein the controller controls the angle of the first damper and the second damper to preferentially supply cool air to the storage room in the kimchi storage mode among the first storage room and the second storage room.

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