KR20100013611A - Refrigerator and control method of refrigerator - Google Patents

Abstract

PURPOSE: A refrigerator which circulates heated air and cooled air smoothly and a refrigerator control method thereof are provided to circulate inside air of a storage room by defrosting a heat exchanger and heating the inside air of the storage room. CONSTITUTION: A refrigerator comprises a storage(400), a heat exchanger(500), a first heater(310), a first ventilation fan(210), and a second ventilation fan(220). The storage comprises a storage room. The heat exchanger cools the storage room. The first heater heats the air of the heat exchanger or the storage room. The first ventilation fan transfers the cool air of the heat exchanger to the storage room. The second ventilation fan is arranged on the lower part of the first ventilation fan in order to circulate the air of the storage room.

Description

Refrigerator and control method of refrigerator

The present invention relates to a refrigerator, and in particular, a first heater, a first blowing fan for transferring cold air of the heat exchanger to the storage compartment, and a lower portion of the first blowing fan to circulate air in the storage compartment. It relates to a refrigerator comprising a second blowing fan.

Conventional refrigerators are those disclosed in Korean Patent Laid-Open Publication No. 2003-0053867.

Front as a drawer with a vertical upper reservoir opened and closed by the upper door

Looking at the overall configuration of the composite kimchi refrigerator having a lower reservoir of the form to be withdrawn, the outer case 10 forming the overall appearance of the kimchi refrigerator and the inner case of the outer case 10 via the heat insulating material (90) An inner container 12 and a hinge 40 formed on an upper wall of the upper container, wherein the outer wall is wound with a heat exchanger 24 for cooling the inside of the refrigerator and a heater 26 for heating the interior of the refrigerator by a flowing refrigerant. In the state that is rotatably mounted on the upper portion of the outer case 10, the door 30 for opening and closing the upper reservoir 20 at the time of withdrawal of kimchi, and is disposed on the front of the kimchi refrigerator to be withdrawn forward The lower chamber 51 to be installed, and the mechanical chamber 70 is provided with a cooling device such as a compressor 60 and a condenser.

In the composite kimchi refrigerator having such a configuration, a method for increasing the thermal insulation characteristics in the lower reservoir to suppress the occurrence of defrost due to temperature variation in the refrigerator and to extend the shelf life of the food, and in the preferred embodiment of the present invention, the lower reservoir ( The structure of changing the cooling method of 50) from the direct cooling method to the indirect cooling method is illustrated.

In order to indirectly cool the lower reservoir 50, the present invention employs a fin tube type heat exchanger 120 having excellent cooling efficiency, and at the same time, cool air supplied by the operation of the fan 110 is evenly supplied throughout the inside of the refrigerator. In order to install a duct 130 having a plurality of blowout port (130a). Although not shown in detail in the drawing, in the fin-tube type heat exchanger 120, a high-temperature, high-pressure refrigerant compressed by the compressor 60 is cooled by a condenser (not shown), and then the cooled refrigerant is introduced. In addition to the pipe, an outlet pipe for cooling the air in the lower reservoir 50 while passing the fin-tube type heat exchanger 120 through the pipe and then sending it back to the compressor 60 is not shown in detail. As such, their connection and placement are well known techniques and further description thereof will be omitted.

Fin-tube type heat exchanger that cools the refrigerant 50 sent from the condenser in the machine room 70 by heat exchange with the air in the refrigerator while passing through the condenser in the machine room 70 by the bracket 122. 120 is mounted. In addition, the fan 110 was attached to the front of the fin type heat exchanger 120 by the fixing table 112. The fan 110 rotates by the motor 114 operated at the time of supply of external electricity and pressurizes the air in the refrigerator to the fin-type heat exchanger 120 to cool the air in the refrigerator.

The air in the chamber, which is pushed toward the fin-type heat exchanger 120 by the operation of the fan 110, is cooled through heat exchange with the refrigerant passing through the heat exchanger 120, and then sent to the duct 130 again. At this time, since the duct 130 is disposed throughout the ceiling of the lower reservoir 50 and is provided with a plurality of ejection openings 130a capable of ejecting cold air, the lower reservoir 50 is provided with the ejection openings of the duct 130. Direct cooling by the cold air emitted from 130a) uniformly and overall prevents temperature deviation in the refrigerator, and allows food, such as vegetables, fruits, and meat, to be kept fresh for a long time.

However, such a conventional refrigerator has a problem that cold or heat is not evenly supplied, and a heater for defrosting the heat exchanger 120 and a heater for heating the storage 50 must be provided separately, thereby increasing the manufacturing cost. have.

The present invention has been made to solve the above-described problem, it is possible to defrost the heat exchanger through a single heater and at the same time can heat the air in the storage compartment, by circulating the air inside the storage compartment to increase the temperature of the air inside the storage compartment It is an object of the present invention to provide a refrigerator that can be kept uniform.

The refrigerator of the present invention for achieving the above object is a storage compartment having a storage compartment, a heat exchanger for cooling the storage compartment, a first heater for heating the heat exchanger, and a cold air of the heat exchanger is transferred to the storage compartment; And a second blowing fan disposed under the first blowing fan and circulating air in the storage compartment.

In the above-described configuration, a duct is disposed inside the storage compartment, the heat exchanger is disposed inside the duct, and the first circulation port disposed above the ventilation hole and the ventilation hole and the second circulation disposed below the ventilation hole. Spheres can be formed.

In addition, a second heater may be further provided, and the second blower fan may be provided with an opening / closing door at the first circulation port for transferring the air warmed by the second heater to the storage compartment.

Refrigerator control method of the present invention for achieving the above object, the input step of receiving the cooling or heating, and when the cooling is input to operate the first blower fan to discharge the cold air of the heat exchanger to the vent of the duct The air flows into the circulation port, and when the heating is input, operating the second blowing fan to discharge the heat of the heater to the circulation port of the duct, and an operation step of introducing air into the ventilation hole of the duct.

According to the refrigerator of the present invention as described above, there are the following effects.

And a first blower fan, a first blower fan for transferring cold air of the heat exchanger to the storage chamber, and a second blower fan disposed under the first blower fan to circulate air in the storage chamber. The heat exchanger may be defrosted at the same time through the heater to heat the air in the storage compartment, and the temperature of the air in the storage compartment may be maintained uniformly by circulating the air in the storage compartment.

A duct is disposed in the storage compartment, the heat exchanger is disposed in the duct, and the duct is formed with a first circulation port disposed above the vent and the vent and a second circulation port disposed below the vent. Cooled air and heated air can be efficiently circulated.

In addition, a second heater is further provided, and the second blowing fan transfers the air warmed by the second heater to the storage compartment, thereby more effectively heating the air inside the storage compartment, and opening and closing the first circulation port. The door is installed to adjust the cooling temperature or heating temperature.

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

For reference, among the configurations of the present invention to be described below, the same configuration as the prior art will be referred to the above-described prior art, and a detailed description thereof will be omitted.

2 is a cross-sectional view of the refrigerator according to a preferred embodiment of the present invention, Figure 3 is a cross-sectional view of the refrigerator according to another embodiment of the present invention.

As shown in FIGS. 2 and 3, the refrigerator of the present embodiment includes a storage compartment 400 having a storage compartment 401, a heat exchanger 500 that cools the storage compartment 401, and the heat exchanger 500. ) Is disposed under the first heater 310, the first blower fan 210 for transferring cold air of the heat exchanger 500 to the storage chamber 401, and the lower portion of the first blower fan 210. And a second blowing fan 220 circulating air in the storage chamber 401.

The reservoir 400 has a space formed therein to form a storage chamber 401, and the storage chamber 401 is formed so that the front thereof is opened.

In addition, the front door 400 is provided with a door 410 for opening and closing the storage compartment 401.

The inner wall of the reservoir 400 is formed so that the support protrusion protrudes, and the shelf 420 is placed on the support protrusion. The shelves 420 are arranged horizontally, and a plurality of shelves 420 are arranged along the vertical direction. Meanwhile, a plurality of through holes may be formed in the shelf 420 so that air in the storage compartment 401 may be smoothly moved.

Further, the duct is disposed inside the storage chamber 401. The duct is formed by forming a partition wall 430 disposed perpendicular to the rear side of the storage chamber 401. Thus, the duct is integrally formed in the reservoir 400, and a flow path 402 is formed between the partition wall 430 and the rear inner wall of the reservoir 400.

The partition wall 430 of the duct includes a vent 441, a first circulation port 431 disposed above the vent 441, and a second circulation port 432 disposed below the vent 441. Is formed.

In addition, the partition 430 of the duct is formed with a housing 440 surrounding the heat exchanger 500. The housing 440 is disposed between the first circulation port 431 and the second circulation port 432.

A plurality of ventilation holes 441 are formed in front of the housing 440 such that the ventilation holes 441 are disposed above the respective shelves 420. Preferably, a louver is provided in the vent 441.

A support protrusion 443 supporting the shelf 420 may protrude from the front surface of the housing 440 to support the shelf 420 more stably.

A vent 442 is formed at the rear upper portion of the housing 440.

The opening and closing door 450 is installed in the first circulation port 431. The opening and closing door 450 is rotatably installed at a central portion of the partition wall 430 and rotated by a driving unit (not shown) such as a motor. The amount of air circulated in the storage chamber 401 is controlled by the opening / closing door 450, so that the cooling temperature or the heating temperature can be efficiently controlled.

Unlike the above description, as shown in FIG. 3, only the louver may be installed in the first circulation port 431 without the opening / closing door 450.

The heat exchanger 500 is vertically disposed vertically in the housing 440 of the duct to cool the storage compartment 401. In this way, the heat exchanger 500 is arranged to evenly supply cold air to the upper and lower portions of the storage compartment 401.

The first heater 310 is installed inside the housing 440 to be disposed behind the heat exchanger 500 to heat the heat exchanger 500. The first heater 310 is also disposed vertically in the vertical direction.

In addition, a drip tray is installed inside the housing 440 to be disposed below the heat exchanger 500. When the heat exchanger 500 is defrosted by the first heater 310, condensed water is collected in the drip tray.

The first blowing fan 210 is installed in the vent 442 to be disposed above the housing 440 to transfer the cool air of the heat exchanger 500 to the storage chamber 401.

The second blowing fan 220 is installed in the second circulation port 432 so as to be disposed under the first blowing fan 210 to circulate air in the storage chamber 401.

Unlike the above, the second heater 320 may be further provided, and the second blowing fan 220 may be disposed at the rear of the second heater 320 to supply air warmed by the second heater 320. Transfer to storage chamber 401.

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

In the refrigerator control method of the present embodiment, an input step of receiving cooling or heating, and when cooling is input, operate the first blower fan 210 to discharge cold air from the heat exchanger 500 to the ventilation hole 442 of the duct. Air is introduced into the first circulation port 431 of the duct, and when heating is input, the second blower fan 220 is operated to heat the first heater 310 to the second circulation port 432 of the duct. And venting the air and introducing air into the vent 442 of the duct.

The input step receives the cooling or heating input from the user through an operation button provided in the storage 400.

In the operating step, when cooling is input in the input step, the controller (not shown) operates the first blowing fan 210, and the second blowing fan 220 stops the operation, operates the heat exchanger 500, and opens and closes it. Door 450 opens.

As a result, the cold air of the heat exchanger 500 flows out into the vent 442 of the duct, and the air inside the storage compartment rises upward through the shelf 420, and then the air flows into the first circulation port 431 of the duct. Is introduced, a part is introduced back into the vent 442 and the other part is transferred to the lower part of the storage chamber 401 through the flow path 402, so that the cool air circulates in the entire storage chamber 401. The air flow during cooling is indicated by a black arrow in FIG.

On the other hand, if frost occurs in the heat exchanger 500 due to continuous cooling, the control unit stops the first blower fan 210, the second blower fan 220, and the heat exchanger 500, and the first heater 310. ) To defrost the heat exchanger 500.

In the operation step, when heating is input in the input step, the second blowing fan 220 is operated, the first blowing fan 210 and the heat exchanger 500 are stopped, and the first heater 310 is It works.

As a result, the air inside the storage chamber 401 rises through the shelf 420 and flows into the vent 442 of the duct, and is heated by the first heater 310. The heat from the first heater 310 exits the housing 440 and descends through the flow path 402, and then is discharged to the second circulation port 432 of the duct, so that the heat circulates through the entire storage chamber 401. Done. The flow of air upon heating is indicated by a white arrow in FIG. 2.

In this way, the air flow direction may be defrosted by changing the flow direction of air at the time of cooling and heating, and heating may be performed at the same time as the first heater 310. Therefore, it is possible to keep kimchi or vegetables fresh, or fermented foods such as kimchi. When heating, the air flows in the opposite direction to the cooling time so that the heat of the first heater 310 is not directed toward the heat exchanger 500, thereby preventing the heat exchanger 500 from being excessively heated.

Further, in the operation step, the control unit may open and close the opening and closing door 450 installed in the first circulation port 431 when cooling, and closes when heating to more effectively circulate the cold air and hot air circulation. Unlike the above, the controller may control the opening degree of the opening / closing door 450 at the time of cooling and heating to adjust the cooling temperature or the heating temperature.

In addition, a second heater 320 is further provided in front of the second blowing fan 220. When the heating is input, the controller operates only the second heater 320 or the first heater 310 and the first heater. By operating the two heaters 320 simultaneously, the heating efficiency can be increased.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art various modifications or variations of the present invention without departing from the spirit and scope of the invention described in the claims below Can be carried out.

As described above, the refrigerator according to the present invention is particularly suitable for an intercooled standing kimchi refrigerator.

1 is a cross-sectional view of a conventional refrigerator.

2 is a cross-sectional view of a refrigerator according to a preferred embodiment of the present invention.

3 is a cross-sectional view of a refrigerator according to another embodiment of the present invention.

** Description of symbols for the main parts of the drawing **

400: storage room 401: storage room

402: Euro 410: door

420: shelf 430: bulkhead

431: first circulation port 432: second circulation port

440 housing 441 vent

442: vent 443: support protrusion

450: opening and closing door

210: first blowing fan 220: second blowing fan

310: first heater 320: second heater

500: heat exchanger

Claims (5)

A storage room equipped with a storage room; A heat exchanger for cooling the storage compartment; A first heater for heating the air of the heat exchanger or the storage compartment; A first blowing fan for transferring cold air of the heat exchanger to the storage compartment; And a second blowing fan disposed under the first blowing fan to circulate air in the storage compartment. The method of claim 1, A duct is disposed in the storage compartment, the heat exchanger is disposed in the duct, and the refrigerator has a vent hole, a first circulation hole disposed above the ventilation hole, and a second circulation hole disposed below the ventilation hole. . The method according to claim 1 or 2, A second heater is further provided, wherein the second blowing fan is configured to transfer the air warmed by the second heater to the storage compartment. The method of claim 2, Refrigerator in which the opening and closing door is installed in the first circulation. An input step of receiving cooling or heating; When cooling is input, the first blower fan is operated to drain the cool air from the heat exchanger to the vent of the duct, and the air is introduced into the circulation port of the duct. And an operation step of discharging heat of the air and introducing air into the ventilation hole of the duct.

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