KR19990028900U - Extended Refrigerator System - Google Patents

Abstract

The present invention relates to a refrigerator, and more particularly, to a function-type refrigerator system in which the cold air of the refrigerator is formed in a structure capable of withdrawing the outside to be utilized for various appliances.

According to a first aspect of the present invention, the technical gist of the present invention is composed of a refrigerator having an external flow path for circulation of cold air to the outside, and an external air device in which the extracted cold air is transferred and kept at a low temperature.

According to a second aspect of the present invention, it is possible to configure a refrigerator function expansion system that connects the refrigerator and the outside device, and further comprises a connector through which cold air is transferred. As described above, the cold air of the refrigerator can be taken out to be used and thus various functions can be extended.

Description

Extended Refrigerator System

The present invention relates to a refrigerator, and more particularly, to a function-expandable refrigerator that is formed in a structure capable of taking out the cold air of the refrigerator to the outside, and to utilize the extracted cold air in various appliances.

In general, in modern civilization, many products are developed to enrich human life due to the development of technology. Among the various products, there are various apparatuses using low temperature, and the representative ones are refrigerators and air conditioners, which are widely used in general home life.

Normally, air conditioners are used for cooling indoors, and refrigerators are used for freezing or refrigerating items requiring low temperature storage. However, the air conditioners and refrigerators generate low-temperature energy by using electricity as a power source. By using low-temperature energy for each purpose, the basic operation principle of the air conditioner and the refrigerator forms the same refrigeration cycle.

Among the devices that add the convenience of human life using the low temperature as described above, the refrigerator generates low temperature cold air using energy therein, and enables the low temperature cold air to keep food in the refrigerator and the freezer at low temperature. .

Hereinafter, a cold air circulation process for achieving the above function in a general refrigerator will be described with reference to the drawings.

1 is a cross-sectional view of the refrigerator showing the internal structure of a typical refrigerator. As shown, the inside of the refrigerator is divided into a freezer compartment 1 and a refrigerating compartment 3 by a barrier 2 filled with insulation. Looking at the supply structure of the cold air, a low-temperature refrigerant flows into the evaporator (1a) installed behind the freezing chamber (1) as the refrigerator is driven. At this time, the air around the evaporator (1a) is exchanged with the low-temperature refrigerant inside the evaporator (1a) to change to low-temperature air, the low-temperature refrigerant inside the evaporator (1a) through a series of processes again to a low-temperature refrigerant Change to the inside of the evaporator 1a.

On the other hand, air that is converted into low temperature (hereinafter referred to as cold air) by heat exchange in the evaporator 1a through which the low temperature refrigerant passes through, ie, some of the cold air, is connected to the shroud 1c by the blowing fan 1b. It is supplied to the freezer compartment 1 via the rest, and the rest is freely dropped through the shroud 1c and supplied to the refrigerator compartment 3.

The supply of cold air to the refrigerating chamber 3 is formed on the front surface of the refrigerating chamber duct 4 while freely falling through the refrigerating chamber duct 4 provided in the longitudinal direction behind the refrigerating chamber 3. The refrigerator is configured to discharge cold air from the rear to the front through 4a).

Through this process, the cold air composed of the freezer compartment 1 and the refrigerating compartment 3 becomes relatively high temperature through heat exchange with the food stored therein, and the air having the high temperature returns to the inside of the barrier 2. The duct 2a moves again to the vicinity of the evaporator 1a. The high temperature air moved to the evaporator 1a side is heat-exchanged with the low temperature refrigerant passing through the evaporator 1a to be converted into low temperature air and circulated again.

As described above, the refrigerator has a structure in which a low temperature refrigerant generated by using electricity is circulated along a constant refrigerant pipe, and the air inside the freezer and refrigerator compartments 1 and 3 exchanges heat with the low temperature refrigerant to maintain a low temperature. To make each food cold.

In addition, in order to keep the necessary items at a low temperature using the refrigerator, it must be stored in the internal space of the refrigerator, and there is a disadvantage that the low temperature refrigerant generated in the refrigerator cannot be used outside the refrigerator. Therefore, the size of the refrigerator needs to be changed according to the amount of goods to be stored, and once the size is released, the refrigerator can store only the items that fit each capacity.

More recently, as life is getting better, the consumer's desire is to prefer a larger-capacity refrigerator, but with the use of a large-capacity refrigerator, not only power is consumed to store the goods, but also ancillary energy consumption. Accordingly, the waste of power is caused. On the other hand, if there are many items to be stored suddenly in the daily life of the existing refrigerator because only the items stored inside can be stored at low temperature, the rest of the items that are not stored in the low temperature storage problem occurs.

This is caused by the low temperature refrigerant being circulated only inside the refrigerator. If the low temperature refrigerant can be used from the outside, the above problems can be solved, and the function of the refrigerator can be variously used.

That is, when the cold air of the refrigerator can be taken out and used when necessary, even when there are many items to be stored, the items are stored in a separate container outside the refrigerator, and the cold air of the refrigerator is extracted and supplied to the container. Can be used separately from the refrigerator can be very convenient.

In addition, the air-cooling system of the general air-cooled product is to cool the ice by using the evaporation heat of the ice by driving the ice inside the blower, it is necessary to take out the ice generated from the refrigerator to use the air cooling. Even in the above case, if the cold air of the refrigerator can be taken out to freeze the ice in the air cooling itself, it can be used more efficiently. In addition to the above case, if the cold air of the refrigerator can be taken out to be used, the present invention can be used not only for the existing ice box and the like but also for various applications.

Accordingly, an object of the present invention is to solve the above problems, and to provide a refrigerator capable of drawing out cold air to the outside, thereby enabling the refrigerator to be used in various apparatuses, thereby enabling the function of the refrigerator to be expanded.

1 is a cross-sectional view showing the internal structure of a conventional refrigerator.

Figure 2 is a cross-sectional view of a refrigerator showing one embodiment of a refrigerator equipped with an external flow path according to the present invention.

3 is a cross-sectional view of a refrigerator showing another embodiment of a refrigerator equipped with an external flow path according to the present invention.

4 is a view showing the external air mechanism according to the present invention,

4A is a perspective view of an outside air mechanism having a closed net environment path of delivery cold air;

4B is a perspective view of an outside air mechanism having an open net environment path for delivered cold air;

5 is a cross-sectional view of the connector according to the present invention.

Figure 6 shows another use state of the embodiment by the combination of the refrigerator and the outdoor device according to the present invention.

7 is a view showing a state of use of another embodiment by the combination of the refrigerator and the outdoor device according to the present invention.

* Explanation of symbols for main parts of the drawings

10: evaporator 12: cold air outlet pipe

12 ': Frozen cold air outflow tube 12 ": Refrigerated cold air outflow tube

14: cold air inlet pipe 16: refrigerator socket portion

20: switch 30: outside mechanism

30a: inner wall of container 30b: outer wall of container

32: container socket 34: cold air passage

34 ': Cold air discharge pipe 34 ": Cold air suction pipe

34a: cold air intake 34b: cold air outlet

36: storage unit 40: connector

42: cold air connection pipe 42a: low temperature cold pipe

42b: high temperature cold pipe 44: first socket terminal

46: second socket terminal 50: blowing fan

A: refrigerator

According to a first aspect of the present invention for achieving the above object, the technical gist of the present invention is composed of a refrigerator having an external flow path for circulation of cold air to the outside and an external air device in which the extracted cold air is transferred and maintained at a low temperature. have.

According to a second aspect of the present invention, it is possible to configure a function-extended refrigerator system that connects the refrigerator and an outdoor device and further comprises a connector through which cold air is transferred. As described above, the cold air of the refrigerator can be taken out to be used and thus various functions can be extended.

The refrigerator may include a cold air outlet portion through which cold cold air flows out of the refrigerator, a cold air inlet portion through which external hot cold air flows in, and an adjustment means for controlling cold air outflow from the cold air outlet portion. The cold air outlet portion is composed of a cold air outlet pipe branched from the upper part of the evaporator and the outlet end is formed on one side of the outer wall of the refrigerator, the cold air inlet part is provided with a cold air inlet pipe is provided on one side of the outer wall and formed on the lower side of the evaporator. Alternatively, the cold air outlet may be a freezing cold air outlet tube branched from the upper part of the evaporator and the outlet end thereof is formed at one side of the outer wall of the refrigerator, and a cold air outlet tube branched at one side of the refrigerator compartment duct and the outlet end formed at one side of the refrigerator outer wall. The cold air inlet may be configured as a cold air inlet pipe having an inlet at one side of the outer wall of the refrigerator and formed at a lower side of the evaporator.

The cold air adjusting means is configured to include a cold air opening and closing membrane installed in the cold air outlet end, and a switch installed on one side of the refrigerator outer wall to control the opening and closing of the opening and closing membrane. One end of the refrigerator outer wall may include an end portion of the cold air outlet and the cold air inlet, and a socket part connected to the connector. According to the control of the switch, it is possible to adjust the amount of cold air supplied to the external air mechanism, so that various external air mechanisms can be configured.

On the other hand, the outside air mechanism, the cold air supply unit for supplying the low temperature cold air delivered through the cold air outlet, the cold air transmission unit for transferring the high temperature cold air generated in the air mechanism to the cold air inlet and end portions of the cold air supply and cold air delivery unit Located and configured to include a socket portion to which the connector is connected. The cold air transfer through the outside air mechanism may be configured to form a closed cold circulation passage through which the cold air supply unit and the cold air transfer unit are circulated along the closed cold air passage at the inlet of the socket and are heat exchanged and the cold air is discharged to the outlet of the socket. . The cold air supply unit may include a cold air discharge pipe having an inlet thereof at the socket part and direct discharge of cold air into the outside air device, wherein the cold air transfer part is provided with a high temperature cold air therein, and an outlet end thereof is provided at the socket part. It may be configured to form an open cold air circulation passage through which cold air enters and exits the outside air mechanism. The connector is provided at both ends thereof with connection terminals connected to the socket part of the refrigerator and the socket part of the external device, respectively, from the low temperature cold engine and the outdoor device to which the low temperature cold air is transferred from the refrigerator to the external device. It consists of hot air pipes through which hot air passes. By varying the length of the connector there is an advantage that it is possible to use the external air mechanism regardless of the position.

Next, the present invention will be described in more detail with reference to the drawings. The constitution according to the present invention is composed of a refrigerator having an external flow path, an external air device using the leaked cold air, and a connection for cold air transfer between the external air device and the refrigerator.

2 is a view showing an embodiment of a refrigerator having an external flow path according to the present invention.

As shown, the cold air outlet pipe 12 for outflowing the low-temperature cold air generated in the evaporator 10 is branched through the top of the evaporator 10, and the cold air circulates the outdoor air mechanism 30 described later. After the cold air inlet pipe 14 is formed in the lower portion of the evaporator 10 side to allow the cold air changed to a high temperature to the evaporator 10 side. In the present embodiment, the cold air outlet pipe 12 is branched from the upper part of the evaporator 10, but is not limited thereto. That is, it is possible to separate through any one of the cold air flow path inside the refrigerating chamber through which the low temperature cold air passes.

And, the socket portion 16 for the low temperature cold air outflow and circulation cold air inflow is located on one side of the outer wall of the refrigerator. End portions of the cold air outlet pipe 12 and the cold air inlet pipe 14 are positioned side by side in the socket portion 16, respectively, and are connected to the connector 40 to be described later to be an outlet for exchanging cold air with the outside. In addition, the cold air outflow pipe 12 and the cold air inflow pipe 14 are positioned at the socket portion 16 through the inner wall and the outer wall of the refrigerator filled with a heat insulating material.

On the other hand, the opening and closing membrane 12a for adjusting the amount of cold air through the outlet pipe 12 is installed at the inlet side of the cold air outflow pipe 12, which is to the outside when not using the external air mechanism 30 to be described later It serves to block the cold air outflow, and also to adjust the amount of cold air supplied according to the use of the outdoor air mechanism (30). That is, to adjust the amount of cold air supplied in accordance with the structure (only for freezing or refrigeration) of the external air mechanism 30 or according to the state (refrigerated storage or freezing storage) of the goods to be stored. The opening and closing of the opening and closing membrane (12a) is made of a structure that can be opened and closed by the general electrical control, the switch unit 20 for adjusting the opening and closing membrane (12a) is provided on one side of the outer wall of the refrigerator.

On the other hand, the external flow path formed in the refrigerator to supply the freezing or refrigeration cold air may be configured differently from the above structure. That is, as shown in FIG. 3, the freezing cold air outlet pipe 12 'for supplying the cold air for the freezer compartment is branched from the upper part of the evaporator 10, and the cold storage air outlet pipe 12 "for supplying the cold air for the refrigerating compartment. It is branched from the upper portion of the refrigerating chamber duct. In the above case, the cool air can be supplied through the outlet pipes 12 'and 12 "according to the use of the outside air mechanism 30, respectively. Therefore, opening and closing membranes 12a 'and 12a "are installed at the inlet of each outlet pipe 12' and 12", and the opening and closing membranes 12a 'and 12a "are configured to be controlled to be opened and closed by electrical control. Of course, a switch 20 for adjusting the opening and closing membranes 12a 'and 12a "will be installed on the outer wall of the refrigerator. When the refrigerator cold air outlet pipe 12 'is opened by the operation of the switch 20 and the refrigerator cold air outlet pipe 12 "is closed, cold air for freezing will be delivered to the outside, and in the opposite case, the refrigerator will be refrigerated. Cool air will be supplied. Of course, when the switch 20 is turned off to close the outlet pipes 12 'and 12 ", the cool air is normally supplied only to the refrigerator to be operated as a general refrigerator.

Next, the external air mechanism 30 will be described. The external air mechanism 30 may be configured in various ways depending on the intended use. The external air mechanism basically includes a storage unit for storing an article, a cold air supply unit for circulating cold air to maintain a low temperature in the storage unit, and It consists of a container socket for receiving cold air from the refrigerator through the cold air supply.

As an embodiment, a general configuration that can be configured simply will be described first. As shown in FIG. 4A, the outside air mechanism 30 is formed of a double wall of the inner wall 30a and the outer wall 30b, and the cold air delivered from the refrigerator flows into one side of the outer wall 30b and circulates in the container. After that, the container socket part 32 which transfers the high temperature cold air which the temperature rose to the refrigerator compartment side is located. Like the refrigerator socket 16, the container socket portion 32 is a cold air outlet for delivering the cold air suction portion 34a through which the cold air supplied from the refrigerator is transferred to the container and the hot air circulated through the container to the refrigerating chamber side ( 343b) is located side by side, and has a structure that can be connected to the connector 40 to be described later.

In addition, the cold air supply unit 34 is connected to the inlet port 34a and the outlet 34b of the container socket part 32, respectively, and has a cold air passage 34 through which the cool air is circulated through the inlet port 34a. ) And the inner wall (30a) is formed spirally. By being configured as described above, the low temperature cold air through the suction port 34a deprives heat of the article stored in the storage unit 36 while passing through the cold passage 34 to make the internal article at a low temperature, and changes to a high temperature. It is transferred back to the refrigerator side through the outlet 34b. Of course, the inner wall 30a container is made of a material such as copper or aluminum having a good heat transfer rate so that the heat exchange is performed smoothly, and the outer wall 30b is preferably made of an insulating material that can be insulated so that heat transfer to the outside is blocked. something to do. To this end, the foam may be filled in the refrigerator between the inner wall 30a and the outer wall 30b.

On the other hand, the cold air supply unit 34 may be configured differently than described above. In the above-described embodiment, the cold air supplied from the refrigerator is transferred along the closed cold air path 34 and performs a function by mutual heat transfer between the freezing path 34 and the goods stored therein. It may be configured to direct the cold air discharge to the article storage unit 36.

That is, as illustrated in FIG. 4B, the cold air discharge pipe 34 ′ is connected to the cold air suction opening 34a of the container socket portion 32 and discharges cold air through the suction opening 34a ′ into the container. And a cold air suction pipe 34 ″ connected to the cold air outlet 34b of the container socket portion 32 and suctioning the high temperature air in the storage portion 36 may be formed on the other side. In the above structure, the cold air delivered through the cold air discharge pipe 34 'is discharged directly into the article storage unit 36, and the cold air of low temperature performs a cooling function by direct contact with the article. The cold air in the storage unit 36 may be sucked through the cold air suction pipe 34 ″ and transferred to the refrigerator side through the cold air outlet 34b of the container socket portion 32. Of course, in this case, in order to prevent heat transfer to the outside by the cold air is discharged directly into the storage unit 36, the walls 30a and 30b of the outside air mechanism should be formed as a heat insulating wall that is well insulated.

Next, the connector 40 will be described. The connector 40 is for connecting each of the socket portions 16 and 32 of the refrigerator and the outside air mechanism 30 to mediate the mutual transfer of cold air. That is, since the refrigerator and the outdoor container 30 are each formed of a rice paddy structure, low temperature cold air generated in the refrigerator is transferred to the external air device 30 through the connector 40, and the heat exchanger is performed in the outdoor air device 30. After the high temperature cold air which has been changed to high temperature is transferred to the refrigerator side through the connector 40, the entire cold air is circulated.

As shown in FIG. 5, the connector 40 has a low temperature cold engine 42a through which the low temperature cold air transmitted from the refrigerator side passes and a high temperature cold engine 42b through the high temperature cold air transmitted from the outside air mechanism 30 side. The cold air connection pipe 42 positioned side by side and the first socket terminal 44 connected to the socket portion 16 of the refrigerator are provided at one end of the cold air connection pipe 42, and the container socket part is provided at the other end. A second socket end 46 connected with the 32 is provided. In addition, the inside of the cold air connection pipe 42 including the low temperature cold engine 42a and the high temperature cold engine 42b is a heat insulating material to prevent mutual heat transfer between the low temperature cold engine 42a and the high temperature cold engine 42b. It would be desirable to fill the inside with

Next, the present invention consisting of the refrigerator and the outside air mechanism 30 and the connector 40 capable of outflowing cold air as described above will be described in detail through the preferred embodiment the operation process thereof.

First, it will be described with reference to Figure 5 showing the combination of the air cooling and the refrigerator. As shown, the present embodiment shows a structure in which the outdoor air mechanism 30 according to FIG. 4A in which cold air is closed and the refrigerator according to FIG. 2 having the cold air outlet pipe 12 are combined. Of course, it may be configured differently from the above.

The user pours water into the inside of the air cooling and operates the switch 20 of the outer wall of the refrigerator A. As a result, the opening / closing membrane 12a is opened to allow the cold air of heat exchanged on the evaporator 10 to be introduced into the cold air outlet pipe 12, and the cold air is transferred to the socket part 16 along the cold air outlet pipe 12. do. The cold air delivered to the socket portion 16 passes through the connector 40 and is transferred to the air cooling through the socket portion 32 of the air cooling, which is the external air mechanism 30.

The delivered cold air flows along the cold air passage 34 formed between the outer wall 30b and the inner wall 30a to deprive heat into the inside to become high temperature, and the water inside the air cooling gradually becomes a low temperature. The cold air changed to the high temperature is circulated through the cold air passage 34 and then transferred to the refrigerator A through the connector 40. The transferred high temperature cold air is introduced into the evaporator 10 through the cold air inlet pipe 14, and is then heat-exchanged with the refrigerant inside the evaporator 10 to be converted into low temperature cold air and circulated again.

On the other hand, the water inside the air cooling is changed to ice by the circulation of the cold air, thereby the operation of the air cooling using the geometric heat of the ice is driven by the driving fan 50 of the air cooling. In the related art, it is quite cumbersome to supply ice from the outside for the operation of the air cooling, but according to the present invention, since ice is supplied by itself, there is an advantage of being quite convenient. Of course, unlike the illustrated air cooling it may be configured to be integral to the top of the refrigerator (A).

On the other hand, unlike the above it may be configured to make the air cooling to the outside air mechanism 30 in the structure shown in Figure 4b to directly supply the cold air.

Next, with reference to Figure 6 showing another embodiment of the present invention will be described. As shown, the configuration according to the present embodiment, as described in Figure 4b, the outdoor air mechanism 30, the cold air is discharged into the article storage unit 36, and the freezing cold air outflow tube 12 'described in FIG. And a refrigerator A having a refrigerated cold air outlet pipe 12 ".

First, when the user wants to store general refrigerated food, such as vegetables in the outdoor appliance 30, the switch to operate the refrigeration cold air outlet pipe 12 "using the switch 20 installed on the outer wall of the refrigerator (A) ( 20. The refrigeration cold air outlet pipe 12 'is closed by the freezing opening and closing membrane 12a', and the cold opening and closing membrane 12a "is closed by the cold storage air outlet pipe 12". The cold air flows into the connector 40 through the socket portion 16, and the cold air flows into the outside air mechanism 30 through the container socket portion 32.

The cold air hydraulically pressurized by the outside air mechanism 30 is discharged directly to the article stored in the article storage unit 36 through the cold air discharge pipe 34 '. The article stored by the discharged cold air is gradually changed to a low temperature, and the internal air whose temperature rises in the article storage unit 36 is transferred to the cold air suction pipe 34 "and passes through the container socket portion 32 to the refrigerator (A). As it is delivered to the) side is delivered to the evaporator 10 side through the cold air inlet pipe 14, the circulation of cold air is made.

Unlike the above, in order to freeze ice, cold air for freezing must flow out. In this case, by operating the switch 20, the refrigeration cold air flows out through the refrigeration cold air outlet pipe (12 ') to freeze the goods stored in the article storage unit 36 of the external air mechanism (30).

In addition, unlike the above, it is also possible to configure the refrigerator and the outdoor device 30. That is, the refrigerator A described with reference to FIG. 2 may be used. In this case, by the operation of the switch 20, the cold air through the cold air outlet pipe 12 is transferred to the freezing cold air or the refrigerated cold air, so that each outside air mechanism 30 Will be supplied to the goods stored in.

In addition, when the outside air mechanism 30 described in FIG. 4A is used, the supplied cold air is circulated along the cold air passage 34 to exchange heat with the items stored in the article storage unit 36 to freeze or refrigerate, and change to a high temperature. The cold air is delivered to the refrigerator A side again, and the cold air will be circulated.

On the other hand, in the above-described embodiment simply described the use of the air-cooling and the general container, the use of the refrigerator according to the present invention is not limited to this, it can be used for various various purposes.

Simply looking at another embodiment, it may be used as an air conditioner. That is, when only a part needs to be cooled, the conventional air conditioner has a structure in which cold air is injected at a fixed position and partial cooling of only a part far away is impossible. However, when using the refrigerator according to the present invention, by simply forming the length of the connector 40, the other end of the connector 40 connected to the socket portion 16 of the refrigerator (A) is located in the portion that needs cooling By operating the refrigerator, cold air can be supplied only where it is needed, so it can be used as a very efficient air conditioner.

As described above, the use of the refrigerator and the outdoor container according to the present invention has the advantage that the capacity of the refrigerator can be increased as it can be efficiently stored, and the user does not need to purchase a separate refrigerator separately. Has the effect of saving.

Another effect of the present invention is that the function of the refrigerator is expanded by applying various types of external air containers such as air cooling.

Claims (11)

A refrigerator having an external flow path for circulation of cold air to the outside; And The extended refrigerator system, characterized in that the cold air is delivered to the outside air mechanism is maintained at a low temperature. The extended type refrigerator system according to claim 1, further comprising a connector connecting the refrigerator and the outside air mechanism and transferring cold air. According to claim 1 or 2, wherein the refrigerator, A cold air outlet through which cold air of the refrigerator flows out; A cold air inlet unit through which external hot air is introduced; And Extended refrigerator system, characterized in that consisting of a control means for controlling the cold air outflow of the cold air outlet. According to claim 3, The cold air outlet portion is formed of a cold air outlet pipe branched from the upper part of the evaporator and the outlet end is formed on one side of the outer wall of the refrigerator, the cold air inlet is provided on the one side of the outer wall is formed to the lower side of the evaporator Extended refrigerator system, characterized in that consisting of cold air inlet pipe. The refrigerator according to claim 3, wherein the cold air outlet part is branched from an upper part of the evaporator, and the outlet end part is formed at one side of the refrigerator outer wall, and the outlet end part is formed at one side of the refrigerator outer wall. And a cold air inlet pipe, wherein the cold air inlet part comprises a cold air inlet pipe having an inlet at one side of an outer wall of the refrigerator and formed at a lower side of the evaporator. The extended refrigerator system according to claim 3, wherein the cold air control unit comprises a cold air opening and closing film installed at a cold air outlet end, and a switch that controls opening and closing of the opening and closing film and is installed at one side of an outer wall of the refrigerator. The refrigerator according to claim 4 or 5, wherein an end portion of the cold air outlet portion and the cold air inlet portion is provided at one side of the outer wall of the refrigerator, and a socket part connected to the connector is formed. The external air mechanism according to claim 1 or 2, A cold air supply unit for supplying low temperature cold air delivered through the cold air outlet; A cold air transfer unit configured to transfer the high temperature cold air generated in the outside air mechanism to the cold air inflow unit; And An end portion of the cold air supply unit and the cold air transfer unit is located, and expandable refrigerator system characterized in that it comprises a socket portion to which the connector is connected. The method of claim 8, wherein the cold air supply unit and the cold air delivery unit, the cold air is introduced at the inlet of the socket portion, the heat exchange while circulating along the closed cold air passage, characterized in that the closed cold air circulation passage through which the outlet cold air of the socket portion flows out. Expandable refrigerator system. The cold air supply unit of claim 8, wherein the cold air supply unit includes a cold air discharge pipe having an inlet thereof at a socket portion and direct discharge of cold air into the outside air device, and the cold air transfer unit is configured to introduce high temperature cold air therein, The extended refrigerator system, characterized in that formed in the socket portion to form an open cold air circulation passage through which cold air enters and leaves the outside air mechanism. According to claim 2, The connector is provided with a connection terminal connected to the socket portion of the refrigerator and the socket of the external air-conditioner, respectively, at both ends, the low-temperature cold engine and the external air-passing device passing through the cold air from the refrigerator to the external air mechanism Extended refrigerator system, characterized in that consisting of a high-temperature cold pipe passing the hot air from the refrigerator to the refrigerator.