KR20130048474A - A refrigerator comprising a sub-stroage chamber and a cooling device - Google Patents

Abstract

PURPOSE: A refrigerant with a cooling device and an auxiliary storing chamber is provided to rapidly cool the inside of the auxiliary storing chamber at ultralow temperature. CONSTITUTION: A refrigerant comprises a body, an auxiliary storing chamber, and a cooling device(300). The body includes a cold air generating chamber with a storing chamber and an evaporator(31). The auxiliary storing chamber is formed inside the storing chamber. The cooling device is arranged inside or outside of the auxiliary storing chamber and supplies cold air to the auxiliary storing chamber so that the inner temperature of the auxiliary storing chamber becomes lower than that of the storing chamber. The cooling device includes a heat radiating member(340) and a thermoelectric element(310). The thermoelectric element includes a heat radiation unit and a heat absorbing unit. The heat radiating member radiates the heat of the thermoelectric element in a cold air generating chamber side.

Description

A refrigerator comprising a sub-stroage chamber and a cooling device}

The present invention relates to a refrigerator, and more particularly, to a refrigerator capable of keeping a storage temperature significantly low by using a thermoelectric element.

Refrigerator is a product that can store or refrigerate food and other storage by using refrigerant cycle.

The conventional refrigerator includes a main body including a storage compartment, a compressor provided in the main body to compress the refrigerant, a condenser to condense 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 stored matter in a refrigerator or to freeze the storage, and a main body is provided with a door for opening and closing the storage compartment.

Storage spaces such as shelves and drawers are provided in a conventional storage room. Recently, a special specialty room or a quenching room is provided in a storage room to reduce a storage temperature of a specific storage item than a storage temperature of a general storage room. .

In the case of such a specialty room or a quenching room, the cold air of the evaporator is introduced using a separate blowing structure, but the lower limit of the temperature of the cold air of the evaporator is not lowered as required by the market, and thus does not satisfy the original purpose. Had a problem.

On the other hand, as shown in the Republic of Korea Patent Publication No. 10-2010-0121334, etc., by applying a thermoelectric element to the refrigerator to realize the miniaturization of the refrigerator, a method for lowering the storage temperature has also been proposed, but in this case, there was a limit to lower the storage temperature However, there was a problem that it takes a long time to meet the temperature.

The present invention is to solve the above problems, the purpose of the present invention is to provide a refrigerator in which the temperature can be reduced quickly while keeping the storage temperature of a specific storage room in the refrigerator significantly lower than that of other storage rooms. have.

The present invention for achieving the object and the main body having a storage chamber, and a cold air generating chamber having an evaporator; The storage compartment is partitioned with the storage compartment in the storage compartment and the internal temperature of the storage compartment may be formed lower than, the interior or exterior of the auxiliary storage compartment, the internal storage temperature of the auxiliary storage compartment is to be formed lower than the storage compartment Including a cooling device for supplying cold air to the secondary storage so that,

The cooling device may include: a thermoelectric element provided between the cold air generating chamber and the auxiliary storage chamber and having a heat dissipation unit and a heat absorbing unit; And a heat dissipation member provided at a heat dissipation unit of the thermoelectric element to dissipate heat of the thermoelectric element in the direction of the cold air generating chamber, and arranged to penetrate and contact the refrigerant pipe constituting the evaporator.

The heat dissipation member is characterized by consisting of a plate having a thickness larger than the diameter of the refrigerant pipe of the evaporator.

The evaporator and a plurality of refrigerant pipes spaced apart from each other; A connecting pipe connecting each refrigerant pipe; And a plurality of cooling fins installed in the coolant pipe and spaced apart from each other, wherein the heat dissipation member is installed in the coolant pipe and is surrounded by the cooling fins.

The heat dissipation member may include a body part provided to be in contact with the thermoelectric element;

It is characterized in that it comprises an insertion hole provided to penetrate the side of the body portion and the refrigerant pipe is inserted and fixed.

The outer circumferential surface of the refrigerant pipe passing through the insertion hole is characterized in that it is arranged to interview the inner circumferential surface of the insertion hole.

The evaporator further includes an installation space in which the heat dissipation member is installed, wherein some of the refrigerant pipes are arranged to be disposed across the installation space.

The cooling device is; A cooling member provided in the heat absorbing portion of the thermoelectric element to absorb heat from the air in the auxiliary storage chamber to cool the air; And a mounting member surrounding the thermoelectric element and contacting the cooling member and the heat dissipation member to prevent heat transfer between the cooling member and the heat dissipation member.

It characterized in that it further comprises a fastening member for connecting and fastening the heat dissipation member, the mounting member and the cooling member.

It characterized in that it further comprises a fastening hole provided in the heat dissipation member, the mounting member and the cooling member is installed through the fastening member.

It is characterized in that it further comprises an opening provided in the partition wall is disposed the mounting member.

Thus, by the operation of the present invention, the inside of the auxiliary storage chamber can be cooled to cryogenic temperature, and the cooling can be induced to be quick.

In particular, since the heat dissipation member connected to the heat dissipation part of the thermoelectric element radiates heat to the cold air generating chamber and the evaporator, the temperature is significantly lower than the cold air generation chamber and the evaporator in the cooling member connected to the cooling part of the thermoelectric element. Can be implemented.

As the cooling device provided separately from the evaporator cools the inside of the auxiliary storage chamber, the cooling rate may be significantly increased, and the cooling temperature may be significantly lowered.

Therefore, there is a convenience that can store the storage requiring quenching or cryogenic storage.

On the other hand, by inserting the heat radiation member constituting the cooling member into the refrigerant pipe of the evaporator, and expands the refrigerant pipe to combine the evaporator and the refrigerant pipe, it is possible to maximize the heat transfer area of the evaporator and the refrigerant pipe, combining them There is also an advantage that a separate fastening member is unnecessary.

1 is a side cross-sectional view of a refrigerator according to the present invention.
2 is a side cross-sectional view of the auxiliary storage chamber according to the first embodiment of the present invention.
3 is a combined perspective and exploded perspective view of the cooling apparatus according to the present invention.
4 is an exploded perspective view of the auxiliary storage chamber of the present invention.
5 to 7 illustrate a process in which the heat radiation member is mounted on the evaporator.
8 is an exploded perspective view of a cooling apparatus including a heat dissipation member mounted on an evaporator.
9 is a combined perspective view of a cooling apparatus including a heat dissipation member mounted on an evaporator.
Figure 10 is a side cross-sectional view showing the flow of air in the secondary storage chamber according to the present invention.

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 compartment and a cold air generating chamber 3 provided behind the storage compartment 2.

The cold air generating chamber 3 and the storage chamber 2 are partitioned by partition walls 4.

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

The storage compartment 2 is provided with a shelf 21 for accommodating a predetermined storage and an auxiliary storage compartment 200 provided below the shelf.

The auxiliary storage compartment 200 is provided to be partitioned from the storage compartment 2, the internal temperature of the auxiliary storage compartment 200 is preferably kept significantly lower than the storage compartment.

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

As described above, the auxiliary storage chamber 200 is provided with a cooling device 300 that is provided separately from the evaporator 31 provided in the cold air generating chamber 3 so that the temperature of the auxiliary storage chamber 200 may be extremely low.

The cooling device 300 is disposed to penetrate the partition wall 4, one end of which is disposed in the auxiliary storage chamber 200, and the other end of which is connected to the evaporator 31.

As will be described later, the cooling device 300 is provided with a thermoelectric element 310, the endothermic action or cooling action for the auxiliary storage chamber 200, the evaporator (3) and the cold air generating chamber (3) It dissipates heat.

As the temperature of the heat dissipating unit of the thermoelectric element 310 decreases, the temperature of the heat absorbing unit or the cooling unit also decreases, so that the temperature of the auxiliary storage chamber 200 is kept at a cryogenic state. The temperature in the vicinity of the heat absorbing part or the cooling part is about -60 ° C.

The auxiliary storage chamber 200 is partitioned from the cold air generating chamber 3 or the storage chamber 2, so that the influence of cold air of the cold air generating chamber 3 or cold air of the storage chamber 2 is limited.

The interior of the auxiliary storage chamber 200 is in a closed state, and the air therein may be cooled and circulated by the cooling device 300.

The auxiliary storage room 200 may be implemented as a housing 210 provided in the storage room 2 and a drawer 220 provided to be slidably movable in the housing 210, but is not limited thereto. .

As shown in FIG. 2, the cooling device 300 is connected to the heat exchanger 31 through the drawer 220, 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 absorbing part (cooling part), a mounting member 320 to which the thermoelectric element 310 is mounted and fixed, and the thermoelectric element 310. A cooling member 330 provided to interview the heat absorbing part (cooling part), a heat radiating member 340 provided to interview the heat radiating part of the thermoelectric element 310, and connected to the evaporator 31, and the cooling It is provided in front of the member 330, the air inlet to move the air toward the cooling member 330, and a blowing fan unit 350 for blowing back the air heat exchanged with the cooling member 330 is provided. .

In the present cooling device, the cooling member 330 is provided to protrude to the inside of the drawer, the heat dissipation member 340 is protruded toward the evaporator 31 of the cold air generating chamber 3 and the evaporator 31 and It is arranged to be connected.

However, the heat dissipation member 340 may be connected to the cold air generating chamber 3 without being connected to the evaporator 31, and may be heat-exchanged with the air inside the cold air generating chamber 3.

The blowing fan unit 350 is mounted to the front of the cooling member 330 as described above, and is provided to protrude inside the drawer 220 like the cooling member 330.

The blowing fan unit 350 and the cooling member 330 are provided to protrude into the drawer 220, so that the air inside the drawer 220 moved by the blowing fan unit 350 is the cooling member. After flow to 330, the heat exchanger with the cooling member 330 may be discharged back into the drawer 220.

 Since the drawer 220 is partitioned from the storage compartment 2 by the housing 210, the temperature of the air inside the drawer 220 is limited by the temperature of the air inside the storage compartment 2. do.

On the other hand, since the drawer 220 is partitioned from the cold air generating chamber 3 by the partition wall 4, it is possible to prevent the cold air of the cold air generating chamber 3 from flowing into the drawer 220. .

Since the temperature of the air inside the drawer 220 cooled by the cooling device 300 is significantly lower than the temperature of the air of the cold air generating chamber 3, when the air of the cold air generating chamber 3 is introduced, The air temperature inside the drawer 220 may increase.

However, as in the present invention, when the communication between the inside of the drawer 220 and the cold air generating chamber 3 is blocked, the temperature inside the drawer 220 can be cooled only by the cooling device 300. Therefore, the cryogenic and rapid cooling pursued in the present invention can be performed.

As described above, since the inner space of the drawer 220 is partitioned from the storage compartment 2 and the cold air generating chamber 3, the drawer 220 through the cooling member 330 cooled by the thermoelectric element 310. Cooling to the inside of the air is more effective, and heat loss can be reduced as compared with the case where the inner space of the drawer 220 communicates with the storage compartment 2 or the cold air generating chamber 3.

3 is a combined perspective view and an exploded perspective view of the cooling apparatus 300 according to the present invention.

As shown in Figure 3 (a), the cooling device 300 is mounted to the blowing fan unit 350, the cooling member 330, the mounting member 320 and the mounting member 320. The thermoelectric element 310 and the heat dissipation member 340 are included.

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

As described above, the cooling member 330 and the blowing fan unit 350 are disposed to protrude into the auxiliary storage chamber (see FIG. 2, 200), and the heat radiating member 340 is the cold air generating chamber (FIG. It is arranged to protrude in the direction of 2, 3).

The side surface of the heat dissipation member 340 is preferably provided with an insertion hole 341, into which the refrigerant pipe of the evaporator (see Fig. 3, 31) is inserted and fixed.

In addition, the mounting member 320 on which the thermoelectric element 310 is mounted is installed and fixed to the partition wall (see FIG. 2 and FIG. 4).

The mounting member 320 is disposed between the cooling member and the heat dissipation member to prevent heat transfer between the cooling member and the heat dissipation member.

As shown in FIG. 4B, the blower fan unit 350 includes a fan housing 351 including a fan motor (not shown), and a blower fan rotatably provided in the fan housing 351. 352).

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

The mall cooling member 330 includes a plate portion 331 and a plurality of straight fins 332 formed in the plate portion 331. A predetermined gap is formed between the fins 332 and the fins 332 to allow air to flow, and to exchange heat with the fins 332 in the flow process.

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

The mounting member 320 is installed at the rear of the cooling member 330, and a mounting hole 321 is formed at the mounting member 320, and the thermoelectric element 310 is disposed at the mounting hole 321. do.

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

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

 When a direct current flows, a temperature difference occurs on both sides of the module due to the thermoelectric effect. This generally refers to a solid state heat pump utilizing the cooling effect exhibited by the Peltier phenomenon.

It is a next-generation environmentally friendly cooling method that breaks the existing cooling method that operates the compressor to circulate the refrigerant. It can be cooled and heated at the same time anywhere through the electrode switching to cool the object at room temperature to -30 ~ + 180 ℃. Overheating can be maintained at a constant temperature.

Since the temperature of the heat absorbing part (cooling part) may be lower as the temperature of the heat radiating part decreases, when the temperature of the heat radiating part is exposed to an atmosphere of about -30 ° C as in the present invention, the temperature of the heat absorbing part is about -60 ° C This can be done.

The mounting member 320 is provided because the thermoelectric element 320 is formed smaller than the size of the cooling member 330 or the heat dissipation member 340, and thus the cooling member 330 or the heat dissipation member 340. In order to facilitate the coupling of the cooling device 300 by placing the mounting member 320 corresponding to the size of the).

The reason why the size of the heat dissipation member 340 or the cooling member 330 is larger than the size of the thermoelectric element 310 is the heat dissipation member 340 or the cooling member 330 from the thermoelectric element 310. To allow the heat or cold to be transferred to the secondary storage compartment (see FIG. 2, 200) or the cold air generating chamber (see FIG. 2, 3) in which the evaporator (see FIG. 2, 31) is installed. For sake.

One side of the thermoelectric element 310 may be a connector (not shown) connected to the wire so that power can be supplied, the connector may be directly connected to the thermoelectric element 310, the mounting member ( It may be arranged in a form buried in 320.

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

The heat dissipation member 340 is also disposed in the shape of a plate, it is preferable to be made of a good thermal conductivity material such as aluminum or copper for heat transfer.

The heat dissipation member 340 is in contact with the thermoelectric element 310 to transfer heat received from the thermoelectric element 310 to the evaporator 31 and the cold air generating chamber 3.

As described above, an insertion hole 341 through which the refrigerant pipe of the evaporator 3 is inserted is coupled to the side surface of the heat dissipation member 340.

The blowing fan unit 350, the heat dissipation member 340, the mounting member 320, and the cooling member 330 are coupled by penetrating a fastening member 360, such as a screw, by such a coupling. The cooling device 300 is configured.

Fastening holes 323, 333, 343, and 353 are formed in the blower fan unit 350, the heat dissipation member 340, the mounting member 320, and the cooling member 330, respectively, for coupling the fastening member 360. do.

Meanwhile, when the thermoelectric element 310 is directly connected to the heat dissipation member 340 and the cooling member 330 without the mounting member 320, the fastening hole may be formed in the thermoelectric element 310.

4 illustrates a configuration of the auxiliary storage chamber 200.

As described above, the auxiliary storage chamber 200 is installed in the storage chamber (refer to FIG. 2 and FIG. 2), and is movable in the housing 210 and the housing 210 which are partitioned from the inner space of the storage chamber 2. It includes a drawer 220 to be provided.

Rollers 211 are provided inside the housing 220, and guide rails 222 are provided at both sides of the drawer 210 to contact the rollers 211 to guide the slide movement of the drawer 220. .

Positions of the guide rail 222 and the roller 211 may be interchanged, and any member capable of guiding a slide movement in addition to the guide rail 222 and the roller 211 may be applied to the present invention. .

The front and rear of the housing 210 is preferably configured to be open. The rear of the housing 210 may be coupled to the front surface of the partition wall 4, and the front of the housing 210 may be opened and closed by the front of the drawer 220.

Accordingly, the inner space of the housing 210 may be partitioned from the storage compartment (see FIG. 2 and FIG. 2) and the cold air generating chamber (see FIG. 2 and FIG. 3), and the housing 210 and the drawer 220. It can maintain the closed circulation of air inside.

The front of the drawer 220 is provided with a handle portion 221 that can be gripped by the user, the rear of the drawer 220 has a through hole 223 through which the cooling device 300 can be exposed Prepared.

The through hole 223 is preferably formed to a size corresponding to the size of the cooling device (300).

Even when the user pulls out the drawer or pushes the drawer by the through hole 223, the cooling device 300 may be separated from the drawer 220 or protrude into the drawer 220.

As described above with reference to FIG. 3, the cooling device 300 includes a thermoelectric element 310 mounted to the blowing fan unit 350, the cooling member 330, the mounting member 320, and the mounting member 320. ) And the heat dissipation member 340.

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

As described above, the cooling member 330 and the blowing fan unit 350 protrudes into the auxiliary storage chamber 200, and the heat dissipation member 340 protrudes toward the cold air generating chamber 3. Is placed.

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

Here, the mounting member 320 is provided as a heat insulating member, thereby preventing heat exchange between the cold air generating chamber 3 and the inner space of the auxiliary storage chamber 200.

The heat dissipation member 340 is provided at the rear of the mounting member 320 and the thermoelectric element 310 and protrudes in the direction of the cold air generating chamber 3 to form the refrigerant pipe 31a of the evaporator 31. Is coupled to perform the heat radiating action on the air of the evaporator 31 and the cold air generating chamber (3).

5 to 7 illustrate a process in which the heat dissipation member 340 is mounted to the evaporator 31.

As shown in FIG. 5, the evaporator includes a coolant pipe 31a and a cooling fin 31b installed in the coolant pipe 31b.

The plurality of cooling fins 31b are provided to be spaced apart from each other in the refrigerant pipe 31b.

Some of the cooling fins 31b have a length longer than others. That is, the cooling fins 31b disposed at the side of the cooling fins 31b are longer than the cooling fins disposed at the center.

The cooling fin 31b disposed on the center side of the evaporator 31 is formed relatively short, and the coolant pipe 31a is disposed across the lower portion of the cooling fin 31b, and the heat dissipation member 340 is disposed. An installation space 31d to be installed is formed.

When the heat dissipation member 340 is installed in the evaporator 31, the coolant pipe 31 a disposed across the installation space 31 d is inserted into the insertion hole 341 of the heat dissipation member 340.

The heat dissipation member 340 is formed on the body portion 342 and the side of the body portion 342, and has insertion holes 341 penetrating both sides, wherein the installation space in the insertion hole 341 The heat dissipation member 340 is temporarily assembled to the evaporator 31 by inserting the coolant pipe 31a disposed across the 31d.

Since the diameter of the refrigerant pipe 31a inserted into the insertion hole 341 is smaller than the diameter of the insertion hole 341, the process of inserting the refrigerant pipe 31a can be easily and quickly performed.

On the other hand, the insertion hole 341 is formed on the side of the body portion 342 of the heat dissipation member 340 is formed in plurality, spaced apart from each other, which is to allow the plurality of refrigerant pipe (31a) can be inserted For sake.

Since a plurality of refrigerant pipes 31a are respectively inserted into the respective insertion holes 341, when the heat dissipation member 340 is fixed, the heat dissipation member 340 is reliably mounted to the evaporator 31. Can be.

As shown in Fig. 6 (a), the refrigerant pipe 31a is inserted into the insertion hole 341 through the refrigerant pipe 31a that crosses the installation space (see Fig. 5, 31d). Since the diameter is smaller than that of the insertion hole (341), the outer peripheral surface of the refrigerant pipe (31a) and the inner peripheral surface of the insertion hole (341) are spaced apart from each other.

In this state, since thermal conductivity between the refrigerant pipe 31a and the heat dissipation member 341 is difficult, a process of coupling the refrigerant pipe 31a and the heat dissipation member 341 to each other is necessary.

As shown in Fig. 6 (b), when high pressure air is blown into the refrigerant pipe 31a, the refrigerant pipe 31a expands, thereby increasing the diameter of the refrigerant pipe 31a. .

Accordingly, the outer circumferential surface of the coolant tube 31a comes into contact with the insertion hole 341 in contact with the inner circumferential surface, thereby allowing heat transfer between the coolant tube 31a and the heat dissipation member 340.

The heat dissipation member 340 is preferably made of a material having excellent thermal conductivity, such as aluminum.

Since the thickness of the heat dissipation member 340 is larger than that of the coolant tube 31a, the coolant tube 31a is inserted into the insertion hole 341 and the coolant tube 31a is expanded. When fastening the 340 to the evaporator 31, there is no need to fix using a separate fastening member.

After passing through the expansion process of the refrigerant pipe (31a) shown in Figure 6 (b), as shown in Figure 7, the heat dissipation member 340 is fixed to the refrigerant pipe (31a) is mounted on the evaporator (31).

The heat dissipation member 340 is in a state surrounded by the cooling fin (31b). The heat dissipation member 340 is preferably installed on the lower side of the evaporator 31, which flows through the cold air generating chamber (see Fig. 1, 3) in which the evaporator 31 and the evaporator 31 is installed. This is because the flow of air moves from bottom to top, with the lowest temperature at the bottom.

That is, as described above, the lower the temperature of the heat dissipation part is, the lower the temperature of the cooling part is, and thus, the quenching and cryogenic temperatures of the auxiliary storage chamber (refer to FIG. 2, 200) are reduced. In order to obtain a state, the heat dissipation member 340 is preferably installed in the coldest part of the cold air generating chamber 3 and the evaporator 31.

When the mounting of the heat dissipation member 340 to the coolant pipe 31a is completed, the end of the coolant pipe 31a is connected by using the U-shaped connecting pipe 31c.

8 and 9, the blower fan unit 350, the cooling member 330, and the mounting member 320 in a state where the heat dissipation member 340 is fixed to the evaporator 31. And the thermoelectric element 310 mounted on the mounting member 320 and the heat dissipation member 340.

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

The blowing fan unit 350, the heat dissipation member 340, the mounting member 320, and the cooling member 330 are coupled by penetrating a fastening member 360, such as a screw, by such a coupling. The cooling device 300 is configured.

Fastening holes 323, 333, 343, and 353 are formed in the blower fan unit 350, the heat dissipation member 340, the mounting member 320, and the cooling member 330, respectively, for coupling the fastening member 360. do.

Meanwhile, when the thermoelectric element 310 is directly connected to the heat dissipation member 340 and the cooling member 330 without the mounting member 320, the fastening hole may be formed in the thermoelectric element 310.

The fastening member 360 is preferably made of a material having a small heat transfer effect, such as synthetic resin to prevent heat transfer.

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

As shown in FIG. 10, when the refrigerant flows into the evaporator 31 by the flow of the refrigerant, the air of the cold air generating chamber 3 is cooled by heat exchange with the evaporator 31.

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

On the other hand, when power is supplied to the thermoelectric element 310 of the cooling device 300, a cooling operation is performed in the cooling unit of the thermoelectric element 310 to maintain a low temperature (about -60 ℃ or less), the thermoelectric The heat dissipation action is performed in the heat dissipation part of the element 310 to maintain a higher temperature (about -30 ° C) than the cooling part.

The cooling unit cools the cooling member 330, and the blowing fan unit 350 operates to introduce air in the auxiliary storage chamber 200 toward the cooling member 330.

The blowing fan unit 350 in FIG. 10 may perform an operation of drawing air from the cooling member 330 (see solid arrow).

Therefore, the air of the auxiliary storage chamber 200 moves to the periphery of the cooling member 330 by the operation of the blowing fan unit 350, and then flows into the cooling member 330.

The air introduced into the cooling member 330 exchanges heat with the cooling member 330, and the temperature drops to a temperature close to the surface temperature of the cooling member 330.

Then, the air is discharged from the cooling member 330 by the blowing fan unit 350, and after passing through the blowing fan unit 350, is introduced into the auxiliary storage chamber 200.

Air flowing into the cooling member 330 moves to the periphery of the cooling member 330, flows into the cooling member 330, passes through the cooling member 330, and then in front of the cooling member 330. The blower fan unit 350 moves to the blower fan unit 350 and is discharged to the front of the blower fan unit 350.

The discharged air may circulate, move, and then move around the cooling member 330 to flow into the cooling member 330.

As such, the air in the auxiliary storage chamber 200 may be cooled while being circulated in the auxiliary storage chamber 200, and may be rapidly cooled while maintaining the internal temperature of the auxiliary storage chamber 200 in a cryogenic state.

In addition, if the auxiliary storage chamber 200 is not opened, since the inflow of air outside the auxiliary storage chamber 200 is limited, the temperature may quickly drop due to the quenching action of the cooling apparatus 300 in a narrow space. Dropped temperatures can be maintained without major changes.

Meanwhile, the blower fan unit 350 may also perform an operation of sucking air and pushing it toward the cooling member 330 (see dotted arrow).

Therefore, air of the auxiliary storage chamber 200 moves to the blowing fan unit 350 by the operation of the blowing fan unit 350, passes through the blowing fan unit 350, and then the cooling member 330. Flows into.

The air introduced into the cooling member 330 exchanges heat with the cooling member 330, and the temperature drops to a temperature close to the surface temperature of the cooling member 330.

In addition, the air is discharged from the cooling member 330 by the discharge pressure of the blower fan unit 350 and flows into the auxiliary storage chamber 200.

The air discharged from the cooling member 330 moves to the front of the auxiliary storage chamber after moving around the cooling member 330, particularly in the vertical direction or the left and right directions.

After moving the air forward, the auxiliary storage chamber 200 is cooled and then sucked back into the blower fan unit 250 to perform a closed cycle of cooling through the cooling member 330 again.

The difference between the case where the blowing fan unit 350 sucks air and the case where air is discharged is as follows.

As shown in the solid line direction of FIG. 10, after the air before cooling is sucked into the periphery of the cooling member 330, after passing through the cooling member 330 and the blowing fan unit 350, the auxiliary storage chamber 200 After being discharged to the center portion, it goes through a cyclic procedure to move to the peripheral portion of the cooling member 330 again.

As shown in the dotted line in FIG. 10, the air before cooling moves toward the rear center of the auxiliary storage chamber 200, is sucked into the blowing fan unit 350, and then the blowing fan unit 350 and the cooling member 330. After passing through sequentially, it is discharged to the peripheral portion of the cooling member 330.

The air discharged from the periphery of the cooling member 330 meets the guide member 225 and is changed in the traveling direction thereof, and undergoes a cyclic procedure of moving to the front of the auxiliary storage chamber 200.

However, the structure in which the heat dissipation member 340 is mounted to the evaporator 31 is not only a structure in which the auxiliary storage chamber 200 is isolated from the cold air generating chamber 3, but also communicates with the cold air generating chamber 3. Of course, it can also be used in the structure.

31: evaporator 31a: refrigerant tube
200: auxiliary storage chamber 210: housing
220: drawer 300: chiller
310: thermoelectric element 320: mounting member
330: cooling member 340: heat dissipation member
341: insertion hole 350: blowing fan unit

Claims (10)

A main body having a storage chamber and a cold air generating chamber having an evaporator;
An auxiliary storage compartment partitioned with the storage compartment in the storage compartment and having an internal temperature lower than that of the storage compartment;
A cooling device provided inside or outside the auxiliary storage chamber and supplying cold air to the auxiliary storage chamber so that an internal temperature of the auxiliary storage chamber is lower than that of the storage chamber,
The cooling device is;
A thermoelectric element provided between the cold air generating chamber and the auxiliary storage chamber and having a heat dissipation unit and a heat absorbing unit;
And a heat dissipation member provided in a heat dissipation unit of the thermoelectric element to dissipate heat of the thermoelectric element in the direction of the cold air generating chamber, and arranged to penetrate and contact the refrigerant pipe constituting the evaporator. The method of claim 1,
The heat dissipation member is a refrigerator, characterized in that consisting of a plate having a thickness larger than the diameter of the refrigerant pipe of the evaporator. The method of claim 2,
The evaporator and a plurality of refrigerant pipes spaced apart from each other;
A connecting pipe connecting each refrigerant pipe;
Installed in the refrigerant pipe and includes a plurality of cooling fins spaced apart from each other,
The heat dissipation member is installed in the refrigerant pipe, characterized in that the refrigerator is arranged to be surrounded by the cooling fins. The method of claim 2,
The heat dissipation member may include a body part provided to be in contact with the thermoelectric element;
Refrigerator comprising an insertion hole provided to penetrate the side of the body portion and the refrigerant pipe is inserted and fixed. 5. The method of claim 4,
And an outer circumferential surface of the refrigerant pipe passing through the insertion hole is arranged to be in contact with an inner circumferential surface of the insertion hole. The method of claim 2,
The evaporator further includes an installation space in which the heat radiation member is installed,
Some of the refrigerant pipe is provided to be arranged across the installation space. The method of claim 2,
The cooling device is;
A cooling member provided in the heat absorbing portion of the thermoelectric element to absorb heat from the air in the auxiliary storage chamber to cool the air;
And a mounting member mounted with the thermoelectric element and disposed between the cooling member and the heat dissipation member to prevent heat transfer between the cooling member and the heat dissipation member. The method of claim 7, wherein
And a fastening member configured to connect the heat radiating member, the mounting member, and the cooling member to be fastened. 9. The method of claim 8,
And a fastening hole provided in the heat dissipation member, the mounting member, and the cooling member and installed through the fastening member. The method of claim 7, wherein
The refrigerator further comprises an opening provided in the partition wall in which the mounting member is disposed.

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