KR101927324B1 - A refrigerator comprising a sub-stroage chamber and a cooling device - Google Patents

Abstract

An object of the present invention is to provide a refrigerator in which the storage temperature of a specific storage room in a refrigerator can be lowered rapidly while keeping the storage temperature of the specific storage room significantly lower than that of other storage rooms.
To achieve these and other advantages and in accordance with the purpose of the present invention, as embodied and broadly described herein, The auxiliary storage chamber is divided into the storage chamber and the inner temperature of which is lower than the temperature of the storage chamber. The auxiliary storage chamber is provided inside or outside the auxiliary storage chamber, And a cooler installed in the auxiliary storage room for receiving the cooler and circulating the cool air generated by the cooler, And a cool air circulation chamber for guiding part of the circulated cool air to be discharged into the auxiliary storage chamber.

Description

[0001] The present invention relates to a refrigerator having a cooling device and an auxiliary storage room,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a refrigerator, and more particularly, to a refrigerator capable of keeping a storage temperature remarkably low using a thermoelectric element.

A refrigerator is a product that can store refrigerated or refrigerated food and other storage by using a refrigerant cycle.

A conventional refrigerator includes a main body having a storage chamber, a compressor provided in the main body for compressing the refrigerant, a condenser for condensing the refrigerant, an expansion valve, an evaporator, and the like.

The cold air generated in the evaporator flows into the storage compartment to store the refrigerated food or the frozen food. The main body is provided with a door for opening and closing the storage compartment.

In a conventional storage room, a storage space such as a shelf and a drawer is provided. Recently, a special storage room has been provided with a special room or a quench room so that the storage temperature of a specific storage is lower than the storage temperature of a common storage room .

In the case of such a special room or a quench chamber, the cold air of the evaporator is introduced using a separate air blowing structure, but the lower limit of the temperature of the cold air of the evaporator is not lowered as required by the market, There was a problem.

On the other hand, as disclosed in Korean Patent Laid-Open No. 10-2010-0121334, a method of lowering the storage temperature while implementing a miniaturization of a refrigerator by applying a thermoelectric element to the refrigerator has been proposed. However, even in this case, , There is a problem that it takes much time to satisfy the temperature.

The object of the present invention is to provide a refrigerator capable of quickly lowering the temperature of a specific storage room in a refrigerator while keeping the storage temperature of the specific storage room significantly lower than that of other storage rooms. have.

To achieve these and other advantages and in accordance with the purpose of the present invention, as embodied and broadly described herein, An auxiliary storage chamber which is partitioned by the storage chamber inside the storage chamber and whose internal temperature can be lower than the temperature of the storage chamber; and a cooling air supply unit provided in the auxiliary storage chamber, And a cooling device installed in the auxiliary storage room for receiving the cooling device, wherein a cool air generated by the cooling device is circulated and a part of the cool air circulated is circulated through the auxiliary storage room, And a cool air circulation chamber for guiding the cool air to be discharged into the auxiliary storage chamber.

The auxiliary storage room includes a drawer which is slidably inserted into the storage room, and a housing which houses the drawer and the cooler circulation room, wherein the drawer and the cooler circulation room are communicable with each other.

A cold air generating chamber provided in the main body and provided with an evaporator; And a partition wall separating the cold room from the auxiliary storage room and the cold air circulation room, wherein the auxiliary storage room and the cold air circulation chamber are kept isolated from the cold air generation room by the partition wall, do.

The cooling device comprising: A thermoelectric element provided between the cold air generation room and the cool air circulation room and including a heat dissipation unit and a heat absorption unit; A heat dissipating member provided in a heat dissipating portion of the thermoelectric element and radiating heat of the thermoelectric element toward the cool air generating chamber; And a heat absorbing member which is provided in the heat absorbing portion of the thermoelectric element and absorbs heat from the air inside the cool air circulating chamber.

The cooling device may further include a blowing fan unit disposed adjacent to the heat absorbing member and provided in the cool air circulating chamber for guiding air in the cool air circulating chamber toward the heat absorbing member.

And the heat absorbing member and the blowing fan unit are disposed inside the cool air circulation chamber.

And the cool air circulation chamber is provided behind the drawer.

The cool air circulation chamber is provided to communicate with the drawer, and is separated from the cool air generation chamber by the partition wall.

 And a guide provided in the cool air circulation chamber for guiding cool air in the cool air circulation chamber to be discharged into the auxiliary storage chamber or guiding the air in the auxiliary storage chamber into the auxiliary storage chamber.

And the guide hole is provided in the form of a duct so as to be insertable into the drawer.

And the guide hole includes a discharge port provided in the cool air circulation chamber and guiding the cool air in the cool air circulation chamber to be discharged into the auxiliary storage chamber.

The guide hole is provided in the cool air circulation chamber and includes an inlet for guiding the air in the auxiliary storage chamber into the auxiliary storage chamber.

And an opening / closing device provided in the guide so as to control the inflow and outflow of air.

And the heat dissipating member is mounted on the evaporator.

And an opening provided in the partition wall to mount the heat dissipating member.

And the heat absorbing member is formed of a flat plate pin.

And the area of at least one of the heat absorbing member and the heat radiating member is larger than the area of the thermoelectric element.

As described above, according to the operation of the present invention, the inside of the auxiliary storage room is partitioned from the storage room and the cold-generating room to be isolated and communicated with the cooling-air circulation chamber, And can be moved from the cool air circulation room to the auxiliary storage room.

Specifically, the circulation speed of the cool air in the cool air circulation chamber can be increased, and the circulation locus can be relatively short, so that the number of times of contact between the air and the cooling member increases, the cooling temperature can be significantly lowered, .

Thus, it is possible to cool the inside of the auxiliary storage room to a cryogenic temperature, and to induce the cooling to be performed quickly.

Particularly, since the heat radiating member connected to the heat radiating portion of the thermoelectric element exerts heat radiation function with respect to the cool air generating chamber and the evaporator, the temperature of the cooling member connected to the cooling portion of the thermoelectric element is significantly lower Can be implemented.

The cooling device provided separately from the evaporator cools only the inside of the auxiliary storage chamber, so that the cooling rate is remarkably increased and the cooling temperature thereof can be remarkably lowered.

Therefore, there is a convenience in that it is possible to store a storage material which needs to be quenched or stored at a very low temperature.

For this purpose, by using the heat radiating member and the cooling member having a larger area than the thermoelectric element, it is possible to maximize the cooling effect on the inside of the auxiliary storage room and the heat radiating effect on the cool air generating chamber and the evaporator.

Meanwhile, by providing a through hole through which a part of the cool air circulation chamber can be inserted, the interference between the drawer and the cool air circulation chamber can be avoided when the drawer is taken out or installed.

1 is a side sectional view of a refrigerator according to the present invention.
2 is a side sectional view of the auxiliary storage room and the cool air circulation chamber according to the first embodiment of the present invention.
3 is a side cross-sectional view of an auxiliary storage room and a cool air circulation chamber according to a second embodiment of the present invention.
4 is an exploded perspective view and an exploded perspective view of a cooling device according to the present invention.
5 is an exploded perspective view of an auxiliary storage room and a cool air circulation chamber according to a first embodiment of the present invention.
6 is an exploded perspective view of an auxiliary storage room and a cool air circulation chamber according to a second embodiment of the present invention.
FIG. 7 is a side sectional view showing the flow of air in the auxiliary storage chamber and the cool air circulation chamber according to the first embodiment of the present invention. FIG.
FIG. 8 is a side sectional view showing the flow of air in the auxiliary storage room and the cool air circulation chamber according to the second embodiment of the present invention. FIG.

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

As shown in FIG. 1, the refrigerator according to the present invention includes a main body 1 having a storage chamber, and a cool air generating chamber 3 provided behind the storage chamber 2.

The cool air generation room (3) and the storage room (2) are partitioned by a partition wall (4).

The cool air generating chamber 3 is provided with an evaporator 31 and a cool air fan 32 for moving the cool air generated in the evaporator 31 to the storage chamber.

In the storage room 2, a shelf 21 capable of storing a predetermined storage and an auxiliary storage room 200 provided under the shelf are provided.

The auxiliary storage 200 may be partitioned from the storage 2 and the internal temperature of the auxiliary storage 200 may be kept significantly lower than the storage.

That is, when the storage chamber 2 constitutes a freezing chamber and its internal temperature is maintained at about -18 to -20 ° C, the temperature of the auxiliary storage chamber 200 is maintained at about -50 to -60 ° C.

The cool air circulation chamber 250 communicating with the auxiliary storage 200 is provided at the rear of the auxiliary storage 200.

A cooling device 300 separately provided from the evaporator 31 provided in the cool air generating chamber 3 is accommodated in the cooler circulation chamber 250 so that the temperature of the auxiliary storage chamber 200 can be extremely low .

The air in the cooling device 300 circulates in the cool air circulation chamber 250 and is rapidly cooled and then discharged from the cool air circulation chamber 250 to the auxiliary storage 200 to be stored in the auxiliary storage 200 It can be maintained at a cryogenic temperature.

The cooling device 300 is disposed through the partition wall 4 and has one end disposed inside the cool air circulation chamber 250 and the other end connected to the evaporator 31.

As described later, the cooling device 300 includes the thermoelectric element 310 to perform an endothermic or cooling action with respect to the auxiliary storage 200, and with respect to the evaporator 3 and the cool air generation chamber 3, Heat dissipation.

In order to maintain the temperature of the auxiliary storage chamber 200 at a cryogenic temperature using the characteristic that the temperature of the heat absorbing portion or the cooling portion is lowered as the temperature of the heat dissipating portion of the thermoelectric element 310 is lowered, 30 ° C, and the temperature around the heat absorbing portion or the cooling portion is about -60 ° C.

The auxiliary storage 200 and the cool air circulation chamber 250 are partitioned from the cool air generation chamber 3 or the storage chamber 2 so that the cool air in the cool air generation chamber 3 or the cool air in the storage chamber 2 Is limited.

The auxiliary storage chamber 200 and the cool air circulation chamber 250 are communicated with each other but they are closed with respect to the storage chamber 2 and the cool air generation chamber 3, 300, and circulated.

The auxiliary storage 200 may include a housing 210 provided in the storage chamber 2 and a drawer 220 slidably mounted on the housing 210. However, .

The cool air circulation chamber 250 is disposed inside the housing 210 and communicates with the drawer 220.

That is, when the drawer 220 is pulled out of the housing 210, the drawer 220 and the cool air circulation chamber 250 are separated, and the drawer 220 is completely contained in the housing 210 The drawer 220 and the cool air circulation chamber 250 are connected and communicated with each other.

2, the cooling device 300 is connected to the heat exchanger 31 through the cool air circulation chamber 250, the housing 210, and the partition wall 4.

The cooling device 300 includes a thermoelectric element 310 having a heat dissipation part and a heat absorption part (cooling part), a mounting member 320 on which the thermoelectric element 310 is mounted and fixed, A cooling member 330 provided to be in contact with the heat absorbing portion (cooling portion), a heat dissipating member 340 provided to be in contact with the heat dissipating portion of the thermoelectric element 310 and connected to the evaporator 31, And a blowing fan unit 350 which is provided in front of the member 330 and moves the air in the direction of the cooling member 330 to suck the air and blow the air exchanged with the cooling member 330 again .

The cooling member 330 protrudes toward the inside of the cool air circulation chamber 250 and the heat dissipation member 340 protrudes toward the evaporator 31 of the cool air generation chamber 3, And is connected to the evaporator 31.

However, it is also possible that the heat dissipating member 340 is not connected to the evaporator 31 but can be protruded toward the cool-gas generating chamber 3 to be heat-exchanged with the air inside the cool-gas generating chamber 3.

The blowing fan unit 350 is mounted in front of the cooling member 330 and protrudes to the inside of the cool air circulation chamber 250 like the cooling member 330 as described above.

The air blowing fan unit 350 and the cooling member 330 protrude into the cool air circulation chamber 250 so that the air inside the cool air circulation chamber 250 moved by the blowing fan unit 350 Flows into the cooling member 330 and performs a heat exchange operation with the cooling member 330, and then can be discharged or circulated back into the cool air circulation chamber 250.

The cool air circulation chamber 250 is provided with a guide hole 251 communicating with the drawer 220. The guide hole 251 allows the cool air of the cool air circulation chamber 250 to flow into the drawer 220 And guiding the air in the drawer 220 to flow into the cool air circulation chamber 250.

The guide 251 is provided with an opening / closing device 252 in the form of a shutter or a damper to communicate or disconnect the cool air circulation chamber 250 and the drawer 220.

It is preferable that the guide hole 251 is formed in a duct shape protruding forward. So that the guide hole 251 can be easily inserted into the drawer 220 by taking a protruded and extended duct shape.

However, the guide hole 251 may be in the form of a hole, and the through hole (see FIG. 5) 223 described later may be formed as a duct extending rearward.

The opening / closing device 252 may be automatically operated by a separate driving device (not shown) connected to a control unit (not shown) of the refrigerator.

The reason why the cooling device 300 is not placed in the drawer 200 but in the separate cooler circulation chamber 250 is because the volume of the inside of the cooler circulation chamber 250 is smaller than that of the drawer 200, The circulation speed of air in the inside of the drawer 200 can be faster than the circulation speed in the drawer 200 and thus the cooling speed of the air inside the drawer 200 can be increased so that the cooler air can be quickly supplied into the drawer 220 It is because.

Since the drawer 220 is separated from the storage compartment 2 by the housing 210, the temperature of the air inside the drawer 220 is affected by the temperature of the air inside the storage compartment 2 Is limited.

Since the drawer 220 is partitioned from the cool air generating chamber 3 by the cool air circulation chamber 250 and the partition wall 4, the cool air in the cool air generating chamber 3 flows into the drawer 220 Can be prevented.

The temperature of the air inside the drawer 220 is significantly lower than the temperature of the air in the cold room 3 due to the inflow of cold air by the cooling device 300 provided in the cool air circulation chamber 250 The temperature of the air inside the drawer 220 may be increased.

When the communication between the inside of the drawer 220 and the inside of the cooler generating chamber 3 is interrupted as in the present invention, the temperature inside the drawer 220 is cooled only by the cooling provided in the cooler circulating chamber 250 It can be cooled by the inflow of cold air by the apparatus 300, so that the cryogenic and rapid cooling pursued by the present invention can be performed.

In this way, the air inside the cool air circulation chamber 250 is rapidly circulated by the blowing fan unit 250 and is cooled by the cooling member 330 cooled by the thermoelectric device 310.

Due to the inflow of air cooled at a low temperature rapidly in the cool air circulation chamber 250 while the cool air circulation chamber 250 is communicated with the drawer 220, And the heat loss can be reduced as compared with the case where the inner space of the drawer 220 is communicated with the storage room 2 or the cold room 3.

Fig. 3 shows a second embodiment of the present invention.

The difference between the second embodiment shown in FIG. 3 and the first embodiment shown in FIG. 2 is that the guide holes 251 of the cold air generating chamber 250 are respectively connected to the inlet 251a and the outlet 251b It is divided.

Also in this case, it is preferable that the guide hole 251 is formed in a duct shape protruding forward. So that the guide hole 251 can be easily inserted into the drawer 220 by taking a protruded and extended duct shape.

Therefore, it is preferable that both the inlet 251a and the outlet 251b are provided in the form of a duct extending forward.

However, the guide hole 251 may be a hole, and the through hole (refer to FIG. 6, 223, 223a, 223b) to be described later may be a duct extending rearward.

The inlet 251a and the outlet 251b are respectively provided with the opening and closing devices 252a and 252b to open or close the inlet 251a and the outlet 251b.

In the second embodiment, the cooling member 330 and the blowing fan unit 350 are protruded to the inside of the cool air circulation chamber 250, which is similar to the first embodiment.

The inlet 251a, the outlet 251b, and the outlet may be vertically or horizontally arranged or may be arranged in various arrangements.

The inlet 251a serves to guide the air flowing into the cool air circulation chamber 250 from the drawer 220 into the cool air circulation chamber 250. [

The discharge port 251b serves to guide the air discharged from the cool air circulation chamber 250 to the drawer 220 toward the drawer 220.

The opening / closing device 252 is connected to a driving device (not shown) such as a separate driving motor as in the first embodiment. The driving device is controlled by a control unit (not shown) of the refrigerator, And the discharge port 251b can be opened or closed independently or simultaneously.

2 except for the constitution of the inlet 251a and the outlet 251b are the same as those of FIG. 2, so a detailed description will be omitted.

4 is an exploded perspective view and an exploded perspective view of the cooling device 300 according to the present invention.

4 (a), the cooling apparatus 300 includes the blowing fan unit 350 and the cooling fan 330 mounted on the cooling member 330, the mounting member 320, and the mounting member 320 A thermoelectric element 310, and the heat dissipating member 340.

The cooling member 330 is attached to the front surface or one surface of the mounting member 320 and the thermoelectric element 310 and the heat radiating member 340 is attached to the rear surface of the mounting member 320 and the thermoelectric element 310 Or other surface.

The cooling member 330 and the blowing fan unit 350 are protruded from the cool air circulation chamber (see FIG. 2) 250 and the heat dissipation member 340 is disposed in the cool air generation room See Fig. 2, 3).

It is preferable that the side surface of the heat dissipating member 340 is provided with an insertion hole 341 through which the refrigerant pipe of the evaporator 31 can be inserted and fixed.

The mounting member 320 on which the thermoelectric element 310 is mounted is fixed to the partition wall 4 (see FIG. 2).

4B, the blowing fan unit 350 includes a fan housing 351 having a fan motor (not shown), and a blowing fan (not shown) provided rotatably in the fan housing 351. [ 352).

The fan housing 351 is provided with a fastening hole 353 through which the fastening member 360 is inserted.

The phase cooler 330 is preferably composed of a plate portion 331 and a flat plate pin composed of a plurality of flat pins 332 formed on the plate portion 331.

A predetermined gap is formed between the pin 332 and the pin 332 to allow air to flow and exchange heat with the pin 332 during the flow.

However, the shape of the pin 332 is not limited thereto, and various shapes are possible.

The mounting member 320 is provided on the rear side of the cooling member 330 and the mounting hole 321 is formed in the mounting member 320. The thermoelectric element 310 is disposed in the mounting hole 321 do.

However, only the thermoelectric element 310 can be interviewed with the cooling member without the mounting member 320.

The thermoelectric module is formed in the form of a module in which N and P type thermocouples are electrically connected in series and thermally connected in parallel.

 When the DC current is applied, a temperature difference occurs on both sides of the module due to the thermoelectric effect. This refers to a solid state heat pump that utilizes the cooling effect typically exhibited by the Peltier phenomenon.

This is the next generation environmentally friendly cooling system that moves away from the existing cooling system that operates the compressor to circulate the refrigerant. It can cool and heat easily anywhere through switching the electrode, so that the object at room temperature can be cooled And can be maintained at a constant temperature through heating.

The temperature of the heat absorbing portion (cooling portion) can be lowered as the temperature of the heat dissipating portion is lowered. Therefore, when the temperature of the heat dissipating portion is exposed to an ambient temperature of about -30 캜 as in the present invention, This can be done.

The reason for placing the mounting member 320 is that the thermoelectric element 320 is formed to be smaller than the size of the cooling member 330 or the heat dissipating member 340. Therefore, the cooling member 330 or the heat dissipating member 340 So that the cooling device 300 can be easily coupled with the mounting member 320.

The mounting member 320 is provided to prevent direct heat exchange between the cooling member 330 and the heat radiating member 340 and to prevent heat exchange between the cool air generating chamber 3 and the cool air circulating chamber 250. [ prevent.

For this purpose, the mounting member 320 is preferably made of a heat insulating material.

The reason why the size of the heat dissipating member 340 or the cooling member 330 is larger than the size of the thermoelectric element 310 is that the heat dissipating member 340 or the cooling member 330, (See FIG. 2) in which the evaporator (see FIG. 2) 31 is installed or the cool air generated in the cool air circulation chamber (refer to FIG. 2) .

A connector (not shown) may be connected to one side of the thermoelectric element 310 so that electric power may be supplied thereto. The connector may be directly connected to the thermoelectric element 310, 320, respectively.

The heat dissipating member 340 coupled to the evaporator (see FIG. 2) 31 is provided at the rear of the mounting member 320 and the thermoelectric element 310.

The heat dissipating member 340 is also disposed in a plate shape and is preferably made of a material having good thermal conductivity such as aluminum or copper for heat transfer.

The heat dissipating member 340 interacts with the thermoelectric device 310 to transfer heat received from the thermoelectric device 310 to the evaporator 31 and the cool air generation chamber 3.

As described above, the insertion hole 341 through which the refrigerant pipe of the evaporator 3 is inserted can be formed on the side surface of the heat dissipating member 340.

The cooling fan 330 is coupled to the cooling fan 330 through a coupling member 360 such as a screw through which the ventilation fan unit 350, the heat dissipation member 340, the mounting member 320, The cooling device 300 is constructed.

Fastening holes 323, 333, 343, and 353 are formed in the cooling fan 330, the mounting member 320, and the cooling fan 330, respectively, for coupling the fastening members 360 do.

If the thermoelectric element 310 is directly connected to the heat radiating member 340 and the cooling member 330 without the mounting member 320, the thermoelectric element 310 may be formed with the fastening hole.

FIG. 5 shows the structure of the auxiliary storage 200 and the cool air circulation chamber 250.

The auxiliary storage 200 includes a housing 210 which is installed in the storage room 2 (refer to FIG. 2) and is partitioned from the internal space of the storage room 2, (Not shown).

A roller 211 is provided in the housing 210 and guide rails 222 are provided on both sides of the drawer 220 to guide sliding movement of the drawer 220 in contact with the roller 211 .

The position of the guide rail 222 and the roller 211 may be changed with each other and any member capable of guiding slide movement in addition to the guide rail 222 and the roller 211 may be applied to the present invention .

The front and rear sides of the housing 210 are preferably open.

The rear of the housing 210 may be coupled to the front of the partition wall 4 and the front of the housing 210 may be opened or closed by the front of the drawer 220.

The drawer 220 is installed in a front space of the inner space of the housing 210 and the cool air circulation room 250 is installed in a rear space of the inner space of the housing 210.

The cool air circulation chamber 250 is accommodated in the housing 210 and the rear of the cool air circulation chamber 250 can be attached to the front surface of the partition wall 4 and fixed thereto.

2) and the cold air generating chamber (see FIG. 2), and the inner space of the housing 210 and the drawer (see FIG. 2) 220 and the inside of the cool air circulation chamber 250 can be maintained.

A guide portion 252 in the form of a duct of the cool air circulation chamber 250 penetrates through the rear surface of the drawer 220, A through hole 223 which can be exposed is provided.

The through hole 223 is formed to have a size corresponding to the size of the rim of the guide hole 250.

When the user pulls the drawer 220 by the through hole 223 and is pulled away from the drawer 220 and pushes the drawer 220, A sphere 252 is inserted into the through hole 223 so that the drawer 220 and the cool air circulation chamber 250 are coupled.

As a result, the drawer 220 and the cool air circulation chamber 250 can be separated or combined without any interference or collision by the through-hole 223 to be in a communicable state.

4, the cooling device 300 includes a blowing fan unit 350 and a thermoelectric element 310 (not shown) mounted on the cooling member 330, the mounting member 320, and the mounting member 320, And the heat dissipating member 340.

The cooling member 330 is attached to the front surface or one surface of the mounting member 320 and the thermoelectric element 310 and the heat radiating member 340 is attached to the rear surface of the mounting member 320 and the thermoelectric element 310 Or other surface.

As described above, the cooling member 330 and the blowing fan unit 350 are protruded to the inside of the cool air circulation chamber 250, and the heat dissipation member 340 protrudes toward the cool air generation chamber 3 Respectively.

The outer edge of the mounting member 320 is fitted to the inner edge of the opening 41 provided in the partition wall 4 so as to move the air between the cold generating chamber 3 and the inner space of the auxiliary storage 200 .

The mounting member 320 is provided as a heat insulating member to prevent heat exchange between the cold air generating chamber 3 and the inner space of the cool air circulating chamber 250.

The heat dissipating member 340 is provided behind the mounting member 320 and the thermoelectric device 310 and protrudes toward the cool air generating chamber 3 to cool the refrigerant pipe 31a of the evaporator 31, So as to perform a heat radiating action on the air in the evaporator (31) and the cool air generating chamber (3).

6 is an exploded perspective view of a second embodiment of the present invention.

Here, a plurality of through holes 223 (223a, 223b) are provided on the rear side of the drawer 220.

The plurality of through holes 223 are provided in the through holes 223 in correspondence with the arrangement of the inlet 251a and the outlet 251b so that the inlet 251a and the outlet 251b in the form of a duct are inserted So that it can be done.

It is preferable that the through holes 223 (223a, 223b) are arranged so as to be spaced from each other so as to correspond to the arrangement that the inlet 251a and the outlet 251b are spaced apart from each other by a predetermined distance in order to prevent mixing of the air to be introduced / Do.

Except for the arrangement of the through holes 223 (223a, 223b) and the arrangement of the inlet 251a and the outlet 251b, the configuration is the same as that of the first embodiment of FIG.

Hereinafter, the operation of the first embodiment of the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 7, when the refrigerant flows into the evaporator 31 by the flow of the refrigerant, the air in the cold generating room 3 is heat-exchanged with the evaporator 31 to be cooled.

The air exchanged with the evaporator 31 is moved toward the storage compartment 2 by a blowing fan 32 (see FIG. 1) of the cold air generating chamber 3.

Meanwhile, when electric power is supplied to the thermoelectric element 310 of the cooling device 300, the cooling part of the thermoelectric element 310 performs a cooling action to maintain a low temperature (about -60 ° C or so) In the heat dissipation portion of the element 310, a heat radiation function is performed, and a temperature (about -30 DEG C) is maintained at a higher temperature than the cooling portion.

The cooling unit cools the cooling member 330. The blowing fan unit 350 operates to allow the air in the cooling circulation chamber 250 to flow toward the cooling member 330.

When the air blowing fan unit 350 operates to move the air toward the cooling member 330, air is cooled by the cooling member 330, and the cooled air is returned to the inside of the cooler circulation chamber 250 And a part of the refrigerant is discharged into the drawer 220 through the guide 251.

The air in the drawer 220 is also introduced into the cool air circulation chamber 250 through the guide hole 251 by the blowing action of the blow fan unit 350, Circulated in the cool air circulation chamber 250 while being mixed with the internal air and cooled by the cooling member 330.

The circulation of air inside the cool air circulation chamber 250 occurs rapidly because the volume of the inside of the cool air circulation chamber 250 is smaller than the volume of the drawer 220, Lt; / RTI >

Therefore, compared with the case where the entire drawer air is cooled, the cooling rate can be remarkably increased, and the cooling temperature can also be remarkably lowered.

The circulating or repetitively cooled air is discharged from the cool air circulation chamber 250 and supplied into the drawer 220 so that the temperature of the air inside the drawer 220 can be rapidly lowered, , The temperature of the storage chamber (see FIG. 1, 2) can be significantly lowered.

Meanwhile, the cooling air circulation chamber (250) is closed through the blowing operation of the blowing fan unit (350) and the cooling action of the cooling member (330) while the open / close device (252) 250, the temperature of the air can be quenched while making the air mild.

In this case, the lowering speed of the temperature can be remarkably accelerated as compared with the case where the cooling is performed while being mixed with the air of the drawer 220.

When the predetermined time has elapsed or the temperature inside the cool air circulation chamber 250 has become a predetermined temperature or lower, the opening / closing device 252 is opened to allow air in the cool air circulation chamber 250 to flow through the drawer 220, respectively.

In this case, the opening / closing device 252 is provided with a device such as a shutter, a blade or a damper as described above, and a driving device (not shown) such as a motor capable of opening and closing the opening / closing device 252 is provided desirable.

Hereinafter, the operation of the second embodiment of the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 8, when the refrigerant flows into the evaporator 31 by the flow of the refrigerant, the air in the cold generating room 3 is cooled by heat exchange with the evaporator 31.

The air exchanged with the evaporator 31 is moved toward the storage compartment 2 by a blowing fan 32 (see FIG. 1) of the cold air generating chamber 3.

Meanwhile, when electric power is supplied to the thermoelectric element 310 of the cooling device 300, the cooling part of the thermoelectric element 310 performs a cooling action to maintain a low temperature (about -60 ° C or so) In the heat dissipation portion of the element 310, a heat radiation function is performed, and a temperature (about -30 DEG C) is maintained at a higher temperature than the cooling portion.

The cooling unit cools the cooling member 330. The blowing fan unit 350 operates to allow the air in the cooling circulation chamber 250 to flow toward the cooling member 330.

When the air blowing fan unit 350 operates to move the air toward the cooling member 330, air is cooled by the cooling member 330, and the cooled air is returned to the inside of the cooler circulation chamber 250 And a part thereof is discharged into the drawer 220 through the discharge port 251b.

The air in the drawer 220 is also introduced into the cool air circulation chamber 250 through the inlet 251a by the blowing action of the blow fan unit 350, And circulated in the cool air circulation chamber (250) while being cooled by the cooling member (330).

The inlet 251a guides the inflow of air from the drawer 220 to the cool air circulation chamber 250 and the outlet 251b guides the air from the cool air circulation chamber 250 to the drawer 220. [ And differs from the first embodiment in guiding air outflow.

The second embodiment is also characterized in that repeated cooling through circulation of air in the cool air circulation chamber 250 is characterized in that the volume inside the cool air circulation chamber 250 is smaller than the volume of the drawer 220, The circulation of the air inside the circulation chamber 250 takes place rapidly, and the circulated air can be repeatedly cooled by the cooling member 330.

Therefore, compared with the case where the entire drawer air is cooled, the cooling rate can be remarkably increased, and the cooling temperature can also be remarkably lowered.

The circulating or repetitively cooled air is discharged from the cool air circulation chamber 250 and supplied into the drawer 220 so that the temperature of the air inside the drawer 220 can be rapidly lowered, , The temperature of the storage chamber (see FIG. 1, 2) can be significantly lowered.

The blowing operation of the blowing fan unit 350 is performed while the inlet 251a and the outlet 251b are closed using the opening and closing devices 252a and 252b to close the cold air circulation chamber 250 itself And the cooling member 330, the temperature of the air can be quenched while keeping the inside of the cool air circulation chamber 250 closed.

In this case, the lowering speed of the temperature can be remarkably accelerated as compared with the case where the cooling is performed while being mixed with the air of the drawer 220.

When the predetermined time has elapsed or the temperature inside the cool air circulation chamber 250 has become a predetermined temperature or lower, the opening / closing device 252 is opened to allow air in the cool air circulation chamber 250 to flow through the drawer 220, respectively.

In this case, the opening / closing device 252 is provided with a device such as a shutter, a blade or a damper as described above, and a driving device (not shown) such as a motor capable of opening and closing the opening / closing device 252 is provided desirable.

As described above, according to the operation of the first and second embodiments of the present invention, when the inside of the auxiliary storage chamber 200 is partitioned from the storage chamber 2 and the cold storage chamber 3, The air circulated in the circulation loop and circulated repeatedly in the auxiliary storage chamber 250 is discharged to the auxiliary storage 200, so that the inside of the auxiliary storage 250 can be cooled to a very low temperature and the cooling can be rapidly performed.

Particularly, since the heat dissipating member 340 connected to the heat dissipating unit of the thermoelectric element 310 dissipates heat to the cool air generating chamber 3 and the evaporator 31, The temperature of the cooling member 330 connected to the cooling air generating chamber 3 and the evaporator 31 can be significantly lowered.

200: auxiliary storage room 210: housing
220: drawer 250: cold circulation room
300: cooling device 310: thermoelectric element
320: mounting member 330: cooling member
340: heat dissipating member 350: blowing fan unit

Claims (11)

A main body having a freezing chamber defined as a space in which food is stored;
A door capable of opening and closing the freezing chamber;
A cool air generation chamber 3 provided in the main body and having an evaporator 31 for supplying cool air to the freezer compartment and a cool air fan 32 for moving cool air generated in the evaporator 31 to the freezer compartment;
A compressor for compressing the refrigerant, a condenser for condensing the refrigerant, an expansion valve;
An auxiliary storage room defined as a space in which food is stored at a lower temperature than the storage room and installed in the freezer room and whose internal temperature can be lower than the temperature of the freezer room;
A partition wall partitioning the cold air generation room and the auxiliary storage room and isolating the room from each other;
A cooling device provided at one side of the auxiliary storage room to generate cool air so that the temperature inside the auxiliary storage compartment is lower than that of the freezer compartment and circulate the generated cool air inside the auxiliary storage compartment;
A cool air circulation chamber located in the vicinity of the auxiliary storage room, in which at least a part of the cooling device is accommodated and cool air circulates;
Wherein the auxiliary storage room includes a housing which is partitioned from the freezing compartment internal space, and means for opening and closing the housing,
The cooling device includes a thermoelectric element having a heat dissipation part and a heat absorption part, a cooling member 330 provided to be in contact with the heat absorption part of the thermoelectric element and absorbing heat from the air inside the auxiliary storage room to cool the air, A heat dissipating member 340 provided to be in contact with the heat dissipating unit of the heat dissipating unit and radiating heat of the thermoelectric device toward the cold air generating room and connected to the refrigerant pipe connected to the evaporator, And a blowing fan unit provided in the circulation chamber for guiding air in the cool air circulation chamber in the direction of the cooling member,
A guide hole is provided between the cool air circulation chamber 250 and the auxiliary storage room, and the guide hole is formed in a duct shape protruding forward,
The rear of the cool air circulation chamber is partitioned and isolated from the cool air generation chamber. A discharge port is provided in front of the cool air circulation chamber behind the auxiliary storage chamber to guide air discharged from the cool air circulation chamber to the auxiliary storage chamber toward the auxiliary storage chamber and,
The cooling member 330 is attached to one surface of the mounting member 320 and the front surface of the thermoelectric element 310 and the heat radiating member 340 is attached to the other surface of the mounting member 320 and the thermoelectric element 310 The blowing fan unit 350, the heat dissipating member 340, the mounting member 320 and the cooling member 330 are coupled by the fastening member 360 to be attached to the cooling unit 330, (300), and the combined cooling device is fixed to the partition wall,
Since the temperature of the air inside the auxiliary storage chamber is significantly lower than the temperature of the air in the cold storage chamber 3 due to the inflow of cool air by the cooling member provided in the cool air circulation chamber 250, The inner space of the housing 210 and the cool air circulation chamber are partitioned from the freezing chamber and the cool air generation chamber so as to prevent the air in the auxiliary storage chamber 3 from flowing into the auxiliary storage chamber 3, Air in the cool air circulation chamber 250 maintains a closed loop,
The air circulation speed in the cool air circulation chamber is made higher than the circulation speed in the auxiliary storage chamber by locating the cooling member in the internal space of the cooler circulation chamber having a volume smaller than that of the auxiliary storage chamber, and,
The heat or cool air that has moved from the thermoelectric element 310 to the heat dissipating member 340 or the cooling member 330 is efficiently supplied to the inner space of the auxiliary storage 200 or the refrigerant of the refrigerant pipe connected to the evaporator 31 The size of the heat dissipating member 340 or the cooling member 330 is larger than the size of the thermoelectric device 310 so that the mounting member 320 as the heat insulating member is disposed between the cooling member and the heat dissipating member And the thermoelectric device 310 is disposed on the mounting hole 321 formed in the mounting member 320 to prevent heat transfer between the cooling member and the heat radiation member,
The heat dissipation member is coupled to the heat dissipation unit of the thermoelectric device so as to lower the temperature of the heat dissipation unit of the thermoelectric device having the characteristic that the temperature of the heat dissipation unit becomes lower as the temperature of the heat dissipation unit becomes lower, And the refrigerant circulating through the expansion valve is subjected to conduction heat exchange with the heat dissipating member, so that the refrigerant discharged from the refrigerant pipe is condensed by the condenser after being compressed by the compressor,
Wherein the temperature of the auxiliary storage chamber is maintained at a temperature lower than that of the freezing chamber. The method according to claim 1,
The guide hole guides the cool air in the cool air circulation chamber to be discharged into the auxiliary storage room or guides the air inside the auxiliary storage room into the cool air circulation chamber and extends from the guide hole in the direction of the rear wall of the auxiliary storage room And wherein the refrigerant is formed. The method according to claim 1,
The housing is opened front and rear,
Wherein the means for opening and closing the housing comprises a drawer (220) which is provided in the housing so as to be capable of being sullied and has a handle on the front surface thereof. The method of claim 3,
Wherein the guide (251) is inserted into the drawer (220). The method of claim 3,
And a through hole (223) through which the guide hole can be inserted is provided on a rear surface of the drawer (220). 6. The method of claim 5,
The through-hole (223) is formed to have a size corresponding to the size of the rim of the guide hole (251), so that the drawer is separated from or coupled to the guide section without interference or collision, . The method according to claim 1,
Wherein the auxiliary storage room maintains a cryogenic temperature. The method according to claim 1,
Wherein a refrigerant tube constituting the evaporator is inserted into the heat dissipating member. The method according to claim 1,
Wherein the cooling device is installed in an opening provided in the partition wall. The method according to claim 1,
Wherein the guide hole (251) of the cool air circulation chamber (250) includes an inlet (251a) and a discharge outlet (251b). 11. The method of claim 10,
The inlet 251a guides the air flowing into the cool air circulation chamber 250 from the auxiliary storage 200 into the cool air circulation chamber 250,
Wherein the discharge port (251b) guides the air discharged from the cool air circulation chamber (250) to the auxiliary storage room (200) toward the auxiliary storage room (200).

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