KR20200141877A - Refrigerator - Google Patents

Abstract

The present invention relates to a refrigerator. More specifically, the refrigerator comprises: a main body where a freezing chamber is provided in a lower portion and a refrigerating chamber is provided in an upper portion; and an ice making chamber separately divided from the refrigerating chamber by an insulation body inside the refrigerating chamber. The ice making chamber comprises: an evaporator where cold air is formed by heat exchange and is discharged; an ice making unit having a mold to produce ice by using the cold air; an ice storage unit transferring and storing the ice; a cold air circulation fan allowing the cold air to circulate from a connection flow passage to a lower flow passage; and an ice making flow passage disposed to pass a lower portion of the mold and connected to the evaporator and the ice storage unit. According to a configuration as described above, the refrigerator has improved ice making performance.

Description

Refrigerator {Refrigerator}

The present invention relates to a refrigerator, and in particular, to a refrigerator in which ice-making performance is improved because cold air in an ice-making compartment is not directly sprayed onto the water surface of a mold.

Among the refrigerators, a refrigerating compartment is formed in the upper part and a freezer compartment is formed in the lower part, and the refrigerator compartment is provided with a hinged-type door divided into left and right sides, and the freezer compartment is a so-called French refrigerator consisting of a drawer type. .

French refrigerators are generally disposed on the upper part of the refrigerator body to make it easier to use a refrigerating compartment that is used relatively more than a freezer, but an ice-making compartment for manufacturing and storing ice is also installed at one side of the upper part of the refrigerator in order to easily take out ice.

The conventional ice making compartment is provided in the refrigerating compartment door, and the ice making compartment is provided in one side of the refrigerating compartment.

As a technology in which the ice making compartment is provided inside the refrigerating compartment, there is US Patent Publication No. 7337620 B2 (Patent Document 1).

In general, the ice making room includes an ice making unit 1 in which water contained in a mold equipped with ice is made of ice, and an ice storage unit 4 in which ice manufactured in the ice making unit 1 is transported and stored as shown in FIG. It is composed by

Meanwhile, unlike Patent Document 1, an evaporator 3 separate from an evaporator used in a freezing chamber or a refrigerating chamber may be provided in the ice making chamber. For technical details related to this, refer to Korean Patent Application Publication No. 10-2009-0012687 (Patent Document 2).

One of the ice-making methods (direct cooling and intercooling) of such conventional refrigerators, the intercooled ice making method, is heat exchanged with the evaporator by a cold air circulation fan 2 provided in the ice making chamber as shown in FIG. 12(a). Ice-making is performed by direct spraying of the cooled dry-cooled air to the water surface of the water contained in the mold. As shown in Fig. 12(b), ice-making is prevented by conduction while passing through the lower flow path formed under the ice-making unit 1 There is a way to do it.

In the intercooled ice making method, an axial-flow fan 2 is used to supply and circulate the dry coolant whose temperature has been lowered through the evaporator 3 into the ice making chamber.

However, the axial cooling air circulation fan 2 is disposed between the evaporator 3 and the mold in a straight line with the ice making unit 1 and directly sprays the cold air that has passed through the evaporator 3 to the water surface in the mold, Ice quality deterioration occurred in which a wave pattern was formed on the surface of the manufactured ice. In addition, in the manner in which cold air passes through the lower flow path of the ice making unit 1, the lower flow path is relatively narrow, so that flow resistance is generated when cold air is supplied, thereby reducing the amount of cool air circulation inside the ice making room.

In addition, in both of the above methods, cold air was supplied unevenly to the ice storage unit 4, resulting in low ice storage performance. Specifically, since the cold air of the ice storage unit 4 reaches the front side of the ice making room and then is transferred to the ice storage unit 4, there is a problem that the storage conditions of the front side and the rear side of the ice storage unit 4 may be changed.

US Patent Publication 7337620 B2 (2008.03.04) Korean Patent Application Publication No. 10-2009-0012687 (2009.02.04)

The present invention is to solve the above-described problem, and an object of the present invention is to provide a refrigerator with improved ice making performance.

In addition, an object of the present invention is to provide a refrigerator in which ice-making performance is improved because cold air in the ice-making chamber is not directly sprayed onto the water surface of the mold.

In addition, an object of the present invention is to provide a refrigerator in which cold air is uniformly supplied to the ice storage unit and ice storage performance of the ice storage unit is improved.

A refrigerator of the present invention for achieving the above object is a refrigerator including a freezing chamber disposed below, a refrigerating chamber disposed above, and an ice making chamber independently provided with the refrigerating chamber, wherein the ice making chamber is configured to lower the temperature of cold air. Evaporator for heat exchange; An ice-making unit in which ice made by cold is accommodated; An ice storage unit disposed below the ice making unit to store the transferred ice; And a cold air circulation fan disposed at a rear side of the cold air circulation passage in the ice making room to suck cool air.

In addition, the refrigerator of the present invention includes a lower flow path disposed under the ice making unit; It further includes a connection flow passage for communicating the evaporator and the lower flow passage.

In addition, in the refrigerator of the present invention, the ice-making unit and the ice storage unit are disposed above and below the ice-making compartment, and the evaporator is disposed on the rear side of the ice-making unit and the ice storage unit, and the cold air circulation fan is It is disposed between the storage unit and the evaporator to circulate cold air from the evaporator to the lower flow path.

In addition, in the refrigerator of the present invention, the ice storage unit has a bottom surface and a side surface, and the top is opened so that the ice produced in the ice-making unit is transferred and cold air is introduced, and the front side and the side of the open top of the ice storage unit are It communicates with the front side and the side of the lower flow path, and the rear of the open upper part of the ice storage part is disposed in front of the suction port of the cold air circulation fan.

The refrigerator of the present invention has the following effects.

In the present invention, the cold air circulation fan induces uniform circulation of cold air in the ice making unit and the ice storage unit by inhaling and circulating cold air, and increases the circulation amount of the cold air, thereby improving ice making performance.

In addition, according to the present invention, ice-making performance is improved because cold air in the ice making chamber is sucked in by a cooling air circulation fan at the rear side of the ice storage unit and is not directly injected to the water surface of the mold by being guided to the lower flow path under the mold.

In addition, according to the present invention, since the cold air in the ice making chamber passes through the lower flow path of the lower surface of the mold, the water contained in the mold starts to freeze from the bottom, so that bubbles are not formed in the ice, and the water is entirely made of ice.

In addition, in the present invention, the supply of cold air to the ice storage unit is uniform and ice storage performance is improved.

1 is a perspective view of a refrigerator equipped with an ice maker according to the present invention
2 is a perspective view of an ice making room according to a preferred embodiment of the present invention
3 is a side view of the ice making compartment shown in FIG. 2
4 is a cross-sectional view of the ice making room shown in FIG. 2
5 is a perspective view showing the inside of the ice making room shown in FIG. 2
6 is a front view showing the inside of the ice making room shown in FIG. 2
7 is a perspective view showing the inside of the ice making room shown in FIG. 6
8 is a perspective view of a lower flow path forming part shown in FIG. 7
9 is a perspective view showing a lower surface of a mold provided in the ice making unit
10 is an exploded perspective view of the ice making room shown in FIG. 2
FIG. 11 is a front view showing the cold air circulation fan shown in FIG. 10
12 is a cross-sectional view of an ice making room provided in a conventional refrigerator

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.

The terminology used herein is only for referring to specific embodiments and is not intended to limit the present invention. Singular shapes used herein also include plural shapes unless the phrases clearly indicate the opposite. The meaning of "comprising" as used in the specification specifies a specific characteristic, region, integer, step, action, element and/or component, and other specific characteristic, region, integer, step, action, element, component and/or group It does not exclude the existence or addition of

When a component is referred to as being "connected" or "contacted" with another component, it is understood that it may be directly connected or in contact with the other component, but other components may exist in the middle. Should be.

1 is a perspective view of a refrigerator 10 equipped with an ice-making compartment 100 according to the present invention, FIG. 2 is a perspective view of an ice-making compartment 100 according to a preferred embodiment of the present invention, and FIG. 3 is shown in FIG. Is a side view of the ice-making compartment 100, FIG. 4 is a cross-sectional view of the ice-making compartment 100 for showing a circulation passage of cold air, and FIG. 5 is a perspective view showing the inside of the ice-making compartment 100 shown in FIG. 6 is the positional relationship between the ice making unit 200 and the ice storage unit 140, and the front outflow path 554, the first and second side outflow paths 551, 552, and the downward injection passage (lower injection passage) in the ice making unit 200 530)) is a front view showing the inside of the ice making room 100 for showing the flow of cold air, FIG. 7 is a perspective view showing the inside of the ice making room 100 for showing the lower flow path in detail, and FIG. 7 is a perspective view of the lower flow path forming part 300, FIG. 9 is a perspective view for showing the lower surface of the mold 220 forming a part of the lower flow path, and FIG. 10 is a motor receiver 150 and a fan receiver ( 161 and the evaporator receiver 111 is an exploded perspective view of the ice making chamber 100 for illustrating in detail, and FIG. 11 is a front view for illustrating the cold air circulation fan 160 shown in FIG. 10.

In the drawing, F refers to the front to the front side, B refers to the rear to the rear side, U refers to the upper side, D refers to the lower side, and S1 and S2 refers to the side or side of one side and the other side.

As shown in FIG. 1, the refrigerator 10 of the present invention includes: a main body (not shown) including a freezer compartment (not shown) disposed at a lower portion and a refrigerator compartment (not shown) disposed at an upper portion; It includes; an ice-making compartment 100 provided independently of the refrigerating compartment.

The main body is provided with drawer-type freezing chamber doors 15 and left and right refrigerating chamber doors 11 for opening and closing the freezing chamber.

The ice making chamber 100 may include an evaporator 110 for exchanging heat to lower the temperature of cold air; An ice-making unit 200 having a mold 220 in which ice made of cold air having a lower temperature passing through the evaporator 110 is accommodated; An ice storage unit 140 disposed under the ice making unit 200 to store ice transferred from the ice making unit 200; A cold air circulation fan 160 disposed at the rear side (B) of the cold air circulation passage inside the ice making room 100 to suck cool air; A lower flow path 520 disposed under the ice making unit 200; And a connection passage 510 communicating the evaporator 110 and the lower passage 520.

The cold air circulation fan 160 sucks in the cold air that has passed through the evaporator 110 and discharges it in the front direction of the ice making chamber 100, that is, in the direction of the ice making unit 200 and the ice storage unit 140.

In the present invention, as shown in FIG. 4, the cold air circulation fan 160 sucks the cold air that has passed through the ice making unit 200 and the ice storage unit 140 and circulates it toward the evaporator 110 so that the ice making unit 200 and It induces uniform circulation of cold air in the ice storage unit 140 and increases the circulation amount of cold air.

In addition, in the present invention, since the cold air that has passed through the evaporator 110 is not directly sprayed to the ice-making unit 200 but is also supplied through the lower flow channel 520, the surface of the water accommodated in the mold 220 of the ice-making unit 200 Ice quality is improved because there is no pattern.

In addition, since the cold air passes through the lower flow path 520, the water contained in the mold 220 starts to freeze from the bottom. As a result, no air bubbles are formed in the produced ice, and all of the water is made of ice. That is, the ice making performance is improved.

Meanwhile, the ice making room 100 further includes a cold air circulation passage in which the ice making unit 200 and the ice storage unit 140 are disposed.

An evaporator 110 is disposed between the front side (A) and the rear side (B) of the cold air circulation passage.

The cool air circulation fan 160 is disposed at the rear side of the cool air circulation passage to suck cool air and circulate the cool air to the front side of the cool air circulation passage.

In addition, in the refrigerator 10 of the present invention, the ice making unit 200 and the ice storage unit 140 are disposed above and below the ice making chamber 100, respectively, and the evaporator 110 is the ice making unit ( 200) and disposed at the rear side of the ice storage unit 140, and the cold air circulation fan 160 is disposed between the ice storage unit 140 and the evaporator 110 to provide cold air from the evaporator 110 to the It circulates in the direction of the lower flow path 520.

As shown in Figure 4, the rear side of the ice storage unit 140, that is, the rear outlet passage 556 to be described later is a cold air circulation fan than the inlet of the evaporator 110 or the outlet 162 of the cold air circulation fan 160 It is disposed close to the inlet 164 of the 160, and the inlet of the evaporator 110 is disposed closer to the discharge port 162 than the inlet 164 of the cold air circulation fan 160.

As shown in FIG. 4, the flow direction of the cold air of the outlet 162 of the cold air circulation fan 160 is parallel to the flow direction of the cold air passing through the evaporator 110, but is opposite to each other. That is, the cold air flows downward from the discharge port 162 of the cooling air circulation fan 160, and the cold air passing through the evaporator 110 flows upward.

The cold air circulation fan 160 includes: a housing 166 having a suction port 164 and a discharge port 162, an impeller 167 being accommodated therein, and having a scroll-shaped space; Including a cut-off unit 163 communicating the space and the discharge port 162; wherein the cold air circulation fan 160 includes a suction port 164 and a discharge port 162, the ice storage unit 140 It is disposed on the side and the evaporator 110 side respectively to suck and circulate cold air.

The present invention has a scroll-shaped housing 166 and a cut-off part 163, and the flow noise and flow rate in the ice making part 200 by the cold air circulation fan 160 having a large air volume and superior static pressure characteristics. Losses are reduced.

In addition, in the refrigerator 10 of the present invention, the ice storage unit 140 has a bottom surface and a side surface, and the upper part is opened so that the ice manufactured in the ice making unit 200 is transferred and cold air is introduced. ), wherein the front and side portions of the open upper portions of the ice storage unit 140 communicate with the front and side portions of the lower flow path 520, and the rear of the open upper portions of the ice storage unit 140 is the It is disposed in front of the inlet 164 of the cold air circulation fan 160.

In this case, a side portion of the open upper portion of the ice storage unit 140 communicates with a space between the side surface of the ice making chamber 100 and the side portion of the ice making unit 200.

Through the above-described configuration, the cold air circulation fan 160 sucks cold air with the ice storage unit 140 disposed in front of the suction unit, so that a negative pressure is formed in the ice storage unit 140. As a result, the cold air in the lower flow passage 520 also moves to the side of the ice storage unit 140 through the ice-making unit 200 side, that is, the downward spray passage 530 to be described later, so that the supply of cold air to the ice storage unit 140 is not It becomes uniform and improves ice storage performance. A more detailed description will be described later.

In addition, through the above-described configuration, since the cold air passes through the lower flow path 520, the water contained in the mold 220 starts to freeze from the bottom. As a result, no air bubbles are formed in the produced ice, and all of the water is made of ice. That is, the ice making performance is improved.

In addition, since the cold air circulation fan 160 inhales cool air from the ice storage unit 140 and discharges it to the evaporator 110, a negative pressure is formed in the ice storage unit 140 and the interior space 141. As a result, the cold air in the lower flow passage 520 is induced to flow to the side of the ice storage unit 140 through the downward spray passage 530, which will be described later, so that the supply of cold air to the ice storage unit 140 becomes uniform, thereby storing ice. The performance is improved. A more detailed description will be described later.

In addition, the cold air passing through the lower flow passage 520 is smoothly supplied to the front side of the ice storage unit 140 in communication with the lower flow passage 520. Accordingly, the supply of cold air to the ice storage unit 140 is uniform, and thus ice storage performance is improved.

On the other hand, the ice making chamber 100 is formed by both side walls 101 facing each other, an upper wall 103, a lower wall, a rear wall 107 connected to the upper, lower, and rear portions respectively, and the walls. It includes an enclosed and opened receiving space (not shown in the drawing), and an opening and closing part 130 provided in the open front of the receiving space.

The opening/closing part 130 has an ice outlet 131 formed therein, and through the ice outlet 131 and a dispenser 13 provided in the refrigerator door 11 on one side, the ice storage unit 140 is Ice can be drained.

Specifically, the opening and closing unit 130 is disposed in front of the control unit 210 and the ice storage unit 140 of the ice making unit 200 to be described later.

The opening/closing unit 130 may be moved forward and backward with respect to the receiving space of the ice making room 100 while the ice storage unit 140 is connected.

As shown in FIG. 4, in the present invention, the ice storage unit 140 is rotated by a motor 143 and a screw 145 that pushes the ice toward the opening/closing unit 130 is provided in the inner space 141.

The motor 143 is disposed between the cold air circulation fan 160 and the rear surface of the ice storage unit 140.

As shown in FIG. 4, the ice storage unit 140, the motor 143, the cold air circulation fan 160, and the evaporator 110 are arranged in the ice making chamber 100 in order from the front side to the rear side.

Meanwhile, as shown in FIGS. 6 and 7, the ice making unit 200 and the lower flow path forming unit 300 are spaced apart from one side wall 101 of the ice making room by a predetermined distance. In addition, the ice storage unit 140 is also spaced apart from one side wall 101 of the ice making room at a predetermined interval. At this time, the width of the ice making unit 200 and the lower flow path forming unit 300 is smaller than the width of the ice storage unit 140.

At this time, the cold air is sprayed to the side of the ice storage unit 140 through the lower spray passage 530, which is a space formed by being spaced apart from the ice making unit 200 and the lower flow path forming unit 300 and one side wall 101 of the ice making room. I can.

On the other hand, as shown in FIGS. 3, 5, and 10, the ice making chamber 100 is provided with a motor receiving body 150 in which the motor 143 is accommodated in the upper side.

An inlet hole 151 through which cool air is introduced and an outlet hole 153 through which cool air flows are formed in the front and rear surfaces of the motor receiver 150, respectively.

As shown in FIG. 5, the inlet hole 151 is formed by penetrating the lower front surface of the motor receiving body 150 in the front-rear direction.

As shown in Figure 10, the outlet hole 153 is formed by passing through the rear surface of the motor receiving body 150 in the front-rear direction.

The outlet hole 153 is disposed in front of the inlet 164 of the cold air circulation fan 160.

Meanwhile, as shown in FIGS. 4 and 10, the ice making chamber 100 further includes a fan receiving body 161 in which the cold air circulation fan 160 is accommodated in the upper side.

The fan receiver 161 is disposed between the motor receiver 150 and the evaporator 110.

The fan receiver 161 includes the housing 166 of the cold air circulation fan 160.

In addition, as shown in FIGS. 3, 4, 5, and 10, the ice making chamber 100 further includes a fan receiver 161 and an evaporator receiver 111 in which the evaporator 110 is accommodated.

The evaporator 110 is accommodated in the rear center of the evaporator receptor 111.

The evaporator 110 is disposed on the rear side of the fan receiver 161.

Meanwhile, the present invention further includes a lower flow path forming part 300 provided between the lower surface of the mold 220 and the ice storage part 140 of the ice making part 200.

Hooks 230 are formed on both sides of the ice making unit 200 so that the lower flow path forming unit 300 is coupled, and hook insertion holes 311 are formed in the lower flow path forming unit 300 by inserting the hook 230 do.

On the other hand, the ice formed in the mold 220 is separated from the mold 220 by an ice-breaking mechanism (not shown) provided in the ice making unit 200 and then falls into the ice storage unit 140.

Meanwhile, as shown in FIGS. 7 and 9, a plurality of partition pieces 221 are formed long in the front and rear directions on the lower surface of the mold 220. At this time, each of the partition pieces 221 is spaced apart from each other by a predetermined interval.

The partition piece 221 has a shape alternately bent to both sides when the mold 220 is viewed straight from the bottom, and has a transverse wave shape among substantially wave shapes.

Meanwhile, in the ice making room 100, a control unit 210 is provided between the opening/closing unit 130 and the mold 220.

Components connected to the ice making unit 200 are accommodated in the control unit 210, such as transferring the ice made to the ice storage unit 140.

Meanwhile, as shown in FIGS. 3 and 4, a drain pipe disposed below the evaporator 110 is formed under the evaporator receiver 111.

The drain pipe serves to drain water formed by melting with a heater (not shown) when frost is low in the evaporator 110.

====== Cold air circulation flow =====

A cold air circulation passage is formed in the receiving space of the ice making room 100.

In the present specification, the cold air circulation passage is referred to as one side of the cold air circulation passage after the outlet portion based on the evaporator 110, and the inlet portion before the evaporator 110 is referred to as the other side of the cold air circulation passage.

Hereinafter, in particular, the configuration of the cold air circulation passage will be described based on the bar shown in FIG. 4.

First, the lower flow path 520 is formed to extend in the front-rear direction.

The lower flow path 520 is formed by being surrounded by the lower flow path forming part 300.

In order to supply cool air well to the lower part of the mold 220, it is preferable that the front and rear length of the lower flow path forming unit 300 is equal to or longer than the front and rear length of the mold 220.

The lower flow path forming unit 300 includes a lower plate 320 of a lower surface of the mold 220 and a bar jubo, and both side plates 310 extending upward from both sides of the lower plate 320.

The lower flow path forming part 300 further includes a flow blocking part 330 protruding convexly from the upper surface of the lower plate 320 and a partition wall 340 disposed on both sides of the flow blocking part 330.

As shown in FIG. 4, when the upward slope portion 331 and the downward slope portion 333 are viewed as one set, a plurality of sets are formed in succession.

The flow-stopping unit 330 is an upward inclined portion 331 that is inclined forward and upward toward the front side, and a downward inclined portion 333 that is inclined forward and downward from the front end of the upwardly inclined portion 331 to the front side. It is made including.

The partition wall 340 is formed to be spaced apart from the flow blocking portion 330 and the mold 220.

The vertical length of the partition wall 340 is longer than the distance from the lower surface of the lower flow path forming part 300 to the lower surface of the mold 220. That is, the upper end of the partition wall 340 is located at the side of the mold 220 rather than both sides.

Meanwhile, as shown in FIG. 7, both side surfaces of the partition piece 221 and the inner surface of the partition wall 340 are spaced apart from each other, and the spaced gap is referred to as a first side outlet passage 551 in this specification.

In addition, the two side surfaces of the mold 220 and the two side plates 310 of the lower flow path forming part 300 are spaced apart from each other, and the spaced gap is referred to as a second side outlet passage 552 in this specification.

The first side outlet passage 551 and the second side outlet passage 552 refer to a side portion of a lower passage that communicates with a side portion of the open upper portion of the ice storage portion.

In the ice making chamber 100 having the above-described configuration, the cold air in the lower flow path 520 is formed in the ice storage unit 140 by the negative pressure, so that the first side outlet passage 551, the second side outlet passage 552, and the lower side After passing through the spray passage 530 in order, it may be sprayed downward through the downward spray passage 530 to be sprayed to both sides of the ice storage unit 140. That is, the cold air sprayed to both sides of the ice storage unit 140 is greater than in the prior art, so that the supply of cold air to the ice storage unit 140 is uniform.

Referring to the above configuration, the lower flow path 520 is surrounded by the rear surface of the control unit 210, the lower surface of the mold 220, the partition wall 340 of the lower flow path forming unit 300 and the flow blocking unit 330. Is formed.

The lower flow passage 520 has an open front lower side, a side portion, and a rear portion.

The cold air circulation passage is spaced between the front outflow passage 554 formed by being spaced apart between the front end of the control unit 210 and the lower passage 520, the upper rear side of the ice storage unit 140 and the lower surface of the lower passage forming unit 300 It further includes a rear outflow path 556 which is a gap.

The cool air circulation passage further includes a suction passage 570 formed between the ice storage unit 140 and the suction port 164 of the cool air circulation fan 160.

The suction passage 570 is the rear outlet passage 556, a spaced apart space between the front surface of the motor receiver 150 and the rear surface of the ice storage unit 140, the inlet hole 151 of the motor receiver 150, It includes a space between the inner space 141 of the motor receiving body 150, the outlet hole 153 of the motor receiving body 150, and the space between the outlet hole 153 and the inlet 164 of the cold air circulation fan 160. Accordingly, the cold air in the inner space 141 of the ice storage unit 140 passes through the suction passage 570 by the suction force of the cold air circulation fan 160 and flows into the cold air circulation fan 160.

The cool air circulation passage further includes a discharge passage formed between the discharge port 162 of the cool air circulation fan 160 and the inlet portion of the evaporator 110.

As shown in FIG. 4, when the ice making chamber 100 is viewed straight from the side, the discharge passage has an approximately'U'-shaped cross-sectional shape.

Specifically, the discharge passage is in communication with the discharge port 162 of the two passages, that is, at the end of the lower passage 581 and the lower passage 581 extending rearward and rearward toward the evaporator 110 The direction is changed to the rear side and extends inclined downwardly toward the evaporator 110 toward the rear side, and includes a direction changing passage 583 communicating with the inlet.

The downward flow path 581 is formed surrounded by the fan receiver 161.

The direction change passage 583 is formed surrounded by the evaporator receiver 111 and the fan receiver 161.

Meanwhile, the connection passage 510 is a straight passage 511 extending from the outlet of the evaporator 110 in the direction of the ice making unit 200, and the lower passage 520 from the straight passage 511 toward the ice making unit 200 It includes an inclined passageway 513 inclined in the direction.

The straight flow path 511 is formed in the evaporator receiver 111 and the fan receiver 161.

In the straight passage 511, the front side and the rear side are respectively in communication with the direction change passage 583 and the outlet of the evaporator 110.

The inclined passageway 513 is formed by being surrounded by the inclined passageway forming pipe 515 provided in the ice making room 100.

The inclined passage 513 communicates with the reduction passage 540 and the straight passage 511 at the front and rear sides, respectively.

The inclined passageway 513 of the present embodiment has a shape in which a cross-sectional area decreases from a rear side to a front side.

On the other hand, the cold air circulation passage further includes a reduction passage 540 for communicating the rear end of the lower passage 520 and the front end of the inclined passage 513.

The vertical width of the reduction passage 540 decreases from the inclined passage 513 to the lower passage 520.

The reduction passage 540 is formed surrounded by a tubular reduction passage forming pipe 541 through which the front and rear sides are penetrated.

Since the cool air in the connection passage 510 is induced to flow only to the lower passage 520 by the inclined passage 513, the amount of cool air supplied to the lower passage 520 is increased than before. In addition, the upper and lower widths of the lower passage 520 are smaller than the upper and lower widths of the connecting passage 510 and are relatively narrow, but the cold air is supplied to the lower passage 520 more smoothly than before through the connecting passage 510 and the inclined passage 513 The ice making ability is improved.

As described above, the cold air circulation passage according to the embodiment of the present invention includes the connection passage 510, the inclined passage 513, the lower passage 520, the first side outlet passage 551, the second side outlet passage 552, and It comprises a downward spray passage 530, a front outlet passage 554, an inner space 141 of the ice storage unit 140, a suction passage 570, and a discharge passage.

The cold air in the ice making chamber 100 passes through the evaporator 110 and decreases in temperature, and then circulates in the order in which the components of the cold air circulation passage are arranged. That is, the cold air that has passed through the evaporator 110 circulates from the front side (A) to the rear side (B) of the cold air circulation passage and is used for ice making and ice storage.

Meanwhile, the cool air circulation fan 160 applied to the present embodiment is a centrifugal fan 160.

Meanwhile, as shown in FIGS. 4, 10, and 11, the centrifugal fan 160 includes an impeller 167 accommodated in the housing 166 and a motor for rotating the impeller 167 (not shown in the drawing). Includes.

The housing 166 connects the first and second plates 166a and 166b and the first and second plates 166a and 166b disposed to face each other on the front and rear sides of the impeller 167 and connects the impeller 167 and the motor. It constitutes a scroll-shaped space 168 defined by the sidewalls 166c surrounding it.

The lower side of the side wall 166c is opened to form the discharge port 162.

As illustrated in FIG. 10, the first plate 166a may be coupled to the motor receiving body 150.

Meanwhile, the motor receiver 150, the fan receiver 161 and the evaporator receiver 111 may be detachably coupled to each other through screw fastening.

The housing 166 has a cut-off point 163 at a point where the scroll-shaped space 168 ends.

When the impeller 167 is rotated by the motor (not shown), the centrifugal fan 160 passes through the space 168 of the housing 166 and cuts off the air sucked through the inlet 164. After moving to the discharge port 162 along the diffusion section gradually expanding from the point 163, the dynamic pressure around the discharge port 162 is recovered to a positive pressure and is discharged to the outside of the discharge port 162.

As described above, although it has been described with reference to a preferred embodiment of the present invention, a person of ordinary skill in the art will diversify 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 changed or modified accordingly.

** Description of key symbols **
10: refrigerator 100: ice making room
110: evaporator 140: ice storage unit
150: motor receptor 160: cold air circulation fan
161: housing 163: cut off portion
200: ice making unit 220: mold
300: lower flow path forming unit 330: flow blocking unit
340: bulkhead 510: connecting passage
520: lower passage 530: downward injection passage
540: reduction passage 551: first side outflow passage
552: second side outlet 554: front side outlet
556: rear outflow path 570: suction path
581,583,585: Directional change route

Claims (4)

A refrigerator including a freezing compartment disposed below, a refrigerating compartment disposed above, and an ice making compartment independently provided from the refrigerating compartment,
The ice making room,
An evaporator for exchanging heat to lower the temperature of the cold air;
An ice-making unit in which ice made by cold is accommodated;
An ice storage unit disposed below the ice making unit to store the transferred ice;
Refrigerator including; a cold air circulation fan disposed at the rear side of the cold air circulation passage in the ice making room to suck cool air The method according to claim 1,
A lower flow passage disposed under the ice making unit;
Refrigerator further comprising a connection passage for communicating the evaporator and the lower passage The method according to claim 2,
The ice making unit and the ice storage unit are disposed above and below the ice making chamber, respectively,
The evaporator is disposed at the rear side of the ice making unit and the ice storage unit,
The cold air circulation fan is disposed between the ice storage unit and the evaporator to circulate cold air from the evaporator to the lower flow path. The method of claim 3,
The ice storage unit consists of a bottom surface and a side surface, and the top is opened so that ice manufactured in the ice making unit is transferred and cold air is introduced,
The front and side portions of the open upper portions of the ice storage unit communicate with the front and side portions of the lower flow passage,
A refrigerator disposed at the rear of the open upper portion of the ice storage unit in front of the suction port of the cooling air circulation fan

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