KR20160059129A - Refrigerator - Google Patents

Abstract

The present invention relates to a refrigerator. The present invention provides a refrigerator including: a cabinet with a storing room; a duct unit providing a passage wherein cold air flows and including multiple vents through which the cold air is discharged to the storing chamber; a guide unit formed inside the duct unit and guiding the cold air discharged to the storing chamber; and a compressor compressing a coolant to supply the cold air to the duct unit. The guide unit includes a phase change material (PCM). A melting point of the PCM is lower than a temperature of the storing room set to operate the compressor. The guide unit guides the cold air flowing to the upper side of the duct unit to be dispersed to both sides. The purpose of the present invention is to provide a refrigerator capable of reducing power consumption.

Description

Refrigerator {Refrigerator}

The present invention relates to a refrigerator, and more particularly, to a refrigerator having improved power consumption.

Generally, a refrigerator includes a machine room at the bottom of the main body. The machine room is generally installed at the lower part of the refrigerator for the center of gravity of the refrigerator, efficiency of assembling, and vibration reduction.

The refrigerator's machine room is equipped with a refrigeration cycle device, which keeps the inside of the refrigerator in a frozen / refrigerated state by using the property of absorbing the external heat while changing the low-pressure liquid refrigerant into gaseous refrigerant, .

The refrigeration cycle apparatus of the refrigerator includes a compressor that changes a low-temperature low-pressure gaseous refrigerant into a high-temperature high-pressure gaseous refrigerant, and a high-temperature high-pressure gaseous refrigerant that is changed in the compressor to a high- A condenser, and an evaporator for absorbing external heat while changing the low-temperature and high-pressure liquid refrigerant changed in the condenser to a gaseous state.

Recently, as the storage capacity of a refrigerator is increased, the power consumption of the refrigerator tends to increase. Research to reduce such power consumption is progressing.

In a typical refrigerator, the upper chamber of the storage compartment has the highest temperature distribution. However, since the compressor is driven on the basis of the temperature of the upper portion, the power consumption is unnecessarily increased even though the temperature of the lower portion of the storage chamber is lower than that of the upper portion.

The present invention provides a refrigerator which can reduce power consumption in a refrigerator.

The present invention also provides a refrigerator in which the temperature inside the storage compartment can be evenly distributed.

To achieve the above object, the present invention provides a cabinet including a storage chamber; A duct unit having a plurality of discharge ports for discharging cool air into the storage chamber and providing a path through which cool air is moved; A guide portion provided in the duct portion and guiding cool air discharged to the storage chamber; And a compressor for compressing the refrigerant so as to supply cold air to the duct portion, wherein the guide portion includes a phase change material (PCM), and the phase change material is disposed in the storage room And the guide part guides the cold air moving to the upper side of the duct part to be divided into two sides.

The guide portion is heat-exchanged with the cool air discharged into the storage chamber in the duct portion, and the cool air provided to the storage chamber while the refrigeration cycle is operated can be raised in temperature by the guide portion.

The guide portion is heat-exchanged with the air discharged into the storage chamber in the duct portion, and the temperature of the storage chamber can be lowered by the guide portion while the refrigeration cycle is not operated.

The duct unit may include a duct cover disposed to be exposed to the storage chamber, a first heat insulating member attached to the rear of the duct cover, and a second heat insulating member disposed between the first heat insulating member and the first heat insulating member, And a second heat insulating member provided on the rear side of the heat insulating member, wherein the guide portion can be provided between the first heat insulating member and the second heat insulating member.

The guide portion may have a tapered portion such that the width of the guide portion increases from the lower portion to the upper portion.

The guide portion may include a body filled with a phase change material therein, and the body may have a higher thermal conductivity than the phase change material.

The body may comprise HDPE 5200B.

It is possible to provide a guide member having a predetermined volume without filling the phase change material at the lower end of the body.

The duct cover may be formed with a protrusion, and the first heat insulating member and the guide portion may be formed with through holes through which the protrusions penetrate.

It is possible that the storage room is a refrigerating chamber and the phase change material has a melting point near 0 degree.

A fan installed in the duct unit, and a controller for driving the fan when the temperature of the storage room rises above a predetermined temperature.

The discharge port can be kept open at all times.

According to the present invention, the power consumption consumed in the refrigerator can be reduced.

Further, according to the present invention, since the temperature inside the storage chamber is evenly distributed, the problem that the compressor is driven due to a relatively high temperature of the storage chamber can be solved.

1 is a front view of a refrigerator according to an embodiment of the present invention;
Fig. 2 is a perspective view of the main part of the embodiment; Fig.
Figure 3 is a more detailed view of Figure 2;
4 is a view showing a state in which some recesses of the embodiment are coupled.
5 shows a guide according to an embodiment.
6 is a control block diagram according to another embodiment;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

The sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience. In addition, terms defined in consideration of the configuration and operation of the present invention may be changed according to the intention or custom of the user, the operator. Definitions of these terms should be based on the content of this specification.

1 is a front view of a refrigerator according to an embodiment of the present invention.

Referring to FIG. 1, a refrigerator according to an embodiment includes a cabinet 1 forming an outer appearance.

The cabinet (1) is provided with a storage room (2) capable of storing food.

The storage room 2 may be formed by an inner case 10 provided inside the cabinet 1. The inner case 10 may include an upper wall 12 and a lower wall 14 to close the inner surface of the storage room 2. The front surface of the storage room 2 may be open, (2) through the front surface of the storage tank (2).

A first door 20 rotatably installed on the cabinet 1 for opening and closing one side of the storage compartment 2 and a second door 20 rotatably installed on the cabinet 1, And a second door (40) for opening / closing the other side of the storage room (2). At this time, when the first door 20 and the second door 40 close the front surface of the storage chamber 2, the storage chamber 2 can be completely closed.

The second door (40) may be provided with a pillar (100) rotatably connected to the first door (20). The pillar 100 may have a generally rectangular parallelepiped shape and may be coupled to the second door 40 so as to be rotatable with respect to the second door 40.

The first door 20 may be provided with a door dike 42 forming a rear outer appearance of the first door 20. Also, the second door 40 may be provided with a door dike 22 forming a rear outer appearance of the second door 40.

The door dies 42 and 22 are provided with baskets 44 and 24, respectively, and various types of food can be stored in the baskets 44 and 24.

The storage room 2 may include a first drawer 34 disposed on the first door 20 side and a second drawer 32 disposed on the second door 40 side. At this time, the first drawer 34 and the second drawer 32 may be disposed on the same horizontal plane. That is, the first drawer 34 and the second drawer 32 can be arranged on the same height in the storage room 2, and on the right and left sides, respectively. The first drawer (34) and the second drawer (32) are independently drawable.

The duct part 200 is provided on the rear wall of the storage room 2, that is, on the rear wall of the inner case 10. At this time, the duct unit 200 may be a passage for supplying cool air generated by the refrigeration cycle apparatus including the compressor 600 installed in the machine room to the storage chamber 2. [

The storage chamber 2 may be provided with a temperature sensor 400 for measuring the temperature of the storage chamber. When the measured temperature of the storage chamber 400 is raised by the user or a set temperature that is set by the user, or when the temperature sensor 400 is operated, the compressor 600 is driven to return the storage chamber 2 to a set temperature or lower Can be cooled.

The duct part 200 may extend vertically in the longitudinal direction of the cabinet 1 as a whole. The cool air supplied by the duct unit 200 may be supplied into the storage chamber 2 by a plurality of discharge openings provided at different heights in the storage chamber 2.

That is, the plurality of discharge ports 212 are formed at various heights, so that the cool air can be discharged at different heights in the storage chamber 2.

At this time, the storage room 2 may be a freezing room, but it may be a refrigerating room. When the storage room 2 is a refrigerating compartment, there may be a difference in that cool air of a relatively high temperature is supplied to the storage compartment 2 as compared with the case of a freezing compartment.

The discharge port 212 may be provided so as to be opened to allow the inside of the storage compartment 2 and the inside of the duct unit 200 to communicate with each other without any separate sealing means.

FIG. 2 is a perspective view of the main part of the embodiment, FIG. 3 is a view showing the detail of FIG. 2 in detail, and FIG.

Referring to FIGS. 2 to 4, a machine room 5 provided with a compressor 600 for compressing refrigerant and the like is provided in the lower portion of the cabinet 1. In the machine room 5, a refrigeration cycle apparatus including a compressor 600 as well as a condenser may be installed.

The duct unit 200 includes a duct cover 210 exposed to the storage chamber 2, a first heat insulating member 220 attached to the rear of the duct cover 210, And a second heat insulating member 240 installed at the rear of the first heat insulating member 220 to form a space through which cool air can pass between the heat insulating member 220 and the second heat insulating member 220.

At this time, the front surface of the duct cover 210 may be exposed to the outside of the storage chamber 2. The duct cover 210 has a plurality of discharge ports 212 so that the chilled air guided by the duct unit 200 can be supplied to the storage chamber 2 through the discharge port 212.

A plurality of the discharge ports 212 of the duct cover 210 are arranged at different heights so that cool air is supplied to the portions of the storage chamber 2 which are different in height while the compressor 600 is driven, The internal temperature of the heat exchanger 2 can be cooled evenly.

The first and second heat insulating members 220 and 240 are formed to have a predetermined thickness so that cool air passing through the inside of the duct unit 200 can be blown to the outside of the cabinet 1 or the duct cover 210, It is possible to prevent the occurrence of dew formation due to the difference in temperature between the storage chamber 2 located on the front surface of the storage chamber 2 and the storage chamber 2.

The temperature of the cool air may be lower than the temperature of the storage chamber 2 when the compressor 600 is driven and cool air is supplied through the duct unit 200. In this case, the temperature difference between the front surface of the duct cover 210 (inside the storage chamber) and the rear surface of the duct cover 210 (inside the duct portion 200) becomes large, and dew can be generated accordingly.

On the other hand, the state where the first and second heat insulating members 220 and 240 are combined can form a square pillar as a whole.

The first heat insulating member 220 has the same number of discharge openings 222 formed at the positions corresponding to the discharge openings 212 formed in the duct cover 210.

The cool air that is moved between the first and second heat insulating members 220 and 240 passes through the discharge port 222 of the first heat insulating member 220 and is then discharged to the outside of the duct cover 210, And may be supplied to the storage chamber 2 through the discharge port 212.

Meanwhile, the guide part 230 is installed between the first and second heat insulating members 220 and 240, and between the first and second heat insulating members 220 and 240, It is possible to guide the cool air passing through the cooling fan. The guide part 230 is provided in the duct part 200 and can guide cold air discharged to the storage room 2. [

The duct cover 210 is formed with a discharge port 214 protruding toward the rear surface of the duct cover 210. The discharge port 214 is formed in the first heat insulating member 220 and the guide part 230, Through holes (224, 234) can be formed, respectively.

The duct cover 210, the first heat insulating member 220, and the guide unit 230 can be easily found at a desired position, and the duct cover 210, the first heat insulating member 220, As shown in FIG.

Referring to FIG. 4, the guide part 230 is disposed along the height direction of the duct part 200 as a whole, but has no structure at the lower part thereof.

The guide part 230 can guide the cool air, which is moved to the upper side of the duct part 200, to be divided into two sides. The duct unit 200 can uniformly discharge the cold air introduced from the lower side along the discharge port 212 formed at a height difference from the duct cover 210. At this time, the guide part 230 may divide the cool air, which is moved upward from the lower part of the duct part 200, to both sides from the center of the duct part 200.

4, the cool air introduced into the lower portion of the duct unit 200 is divided into two sides of the guide unit 230 and supplied to the storage chamber 2 through the discharge port 222, .

5 is a view showing a guide unit according to an embodiment.

5A, the guide unit 230 includes a body 231 forming an overall appearance and a phase change material 233 filled in the body 231 .

Meanwhile, a through hole 234 is formed at the center of the guide part 230 so that the discharge port 214 of the duct cover 210 can be inserted. The through hole 234 is an opening that penetrates the front and rear surfaces of the guide portion 230. The through hole 234 may be formed in a closed structure such that the phase change material 233 filled in the body 231 does not leak to the outside. Can be formed.

The guide part 230 may have a tapered part 232 so that the width of the guide part 230 increases from the lower part to the upper part. At this time, the tapered portion 232 is formed in order to reduce the momentum loss due to the resistance by the guide portion 230 when the cold air introduced from the lower portion of the duct portion 200 is moved to the upper portion of the duct portion 200 And is a structure provided for sequentially generating changes in cross-sectional area.

At this time, it is preferable that the body 231 has a higher thermal conductivity than the phase change material 233. Since the phase-change material 233 is a liquid-to-solid phase-converted material based on a specific temperature, the phase-change material 233 must be filled in the body 231.

It is necessary for the body 231 to allow the external temperature change to be transmitted to the phase change material 233 well. In order to efficiently use the phase change material 233, the body 231 has a thermal conductivity higher than that of the phase change material 233 so that the phase change material 233 can be easily heat- .

Specifically, it can be made of HDPE 5200B. HDPE (5200B) is characterized by high stiffness, good resistance at low temperature and low temperature and chemicals resistance. Since HDPE (5200B) is a material provided by HONAM PETROCHEMICAL CORP., Detailed description is omitted.

Of course, the body 231 may have a certain degree of strength to prevent the phase change material 233 from leaking to the outside due to volume change or external impact due to a temperature change applied to the phase change material 233 .

Preferably, the phase change material 233 melts at a temperature lower than the temperature of the storage chamber in which the compressor 600 is driven. The phase change material 233 can emit a lot of cool air when it changes from solid to liquid. The temperature of the storage chamber 2 may be lowered before the temperature of the storage chamber 2 reaches the set temperature at which the compressor 600 is driven while the compressor 600 is not driven, It is preferable that the stored cool air is supplied to the storage chamber 2 so that the temperature of the storage chamber 2 is slowly raised. Therefore, since the starting time of the compressor 600 can be delayed, energy can be saved.

Meanwhile, if the storage room 2 is a refrigerator room in which food is stored at room temperature, it is preferable that the phase change material 233 has a melting point of about 0 degree. The melting point is a temperature at which a phase transition from a solid to a liquid occurs. The phase change material 233 may accumulate a higher amount of energy at a melting point or freezing point at which the phase is changed, and then discharge it to the outside. That is, if the melting point of the phase change material 233 is about 0 degrees, the phase change material 233 can absorb a large amount of cool air in the vicinity of 0 degrees and absorbs a larger amount of cool air, A large amount of cold air can be released.

Since Fig. 5B is an embodiment different from Fig. 5A, the differences will be mainly described, and a description of the same portions will be omitted.

5B, the body 231 having the phase change material 233 inserted therein is disposed on the upper side. A guide member 239 having a predetermined volume without the phase change material 233 inserted therein is provided in the lower portion of the body 231.

At this time, the shape of the guide member 239 may be the same as the lower portion of the body 231 of FIG. 5A. However, there is only a difference in that the phase change material is not inserted into the guide member 239.

Generally, the temperature of the upper side of the storage chamber 2 tends to be relatively higher as time passes without the compressor 600 being driven. This is because cold cold air tends to stay below the upper side. In this embodiment, the phase change material (PCM) 233 is relatively positioned on the upper side so that the phase change material (PCM) 233 contained in the phase change material The internal temperature of the storage chamber 2 can be kept uniform by the cold air without any deviation between the upper and lower portions.

Since the phase change material 233 can accumulate cold air, cool air can be supplied to the storage chamber 2 by the phase change material 233 when the temperature of the upper portion of the storage chamber 2 is raised .

1 to 5, when the temperature of the storage chamber 2 is raised in a state where the compressor 600 is not driven, the phase change material 233 Can be supplied to the storage chamber 2 through the discharge ports 212 and 222. [ Since the temperature of the storage chamber 2 is relatively high and the temperature of the phase change material 233 is relatively low while the temperature of the storage chamber 2 is raised, A natural convection may be generated between the two. Therefore, the temperature rise of the storage chamber 2 is delayed as compared with the case where the phase change material 233 is not present.

Therefore, the frequency of lowering the temperature of the storage chamber 2 by driving the compressor 600 may be reduced, or the start time for starting the compressor 600 may be delayed. That is, the energy consumption of the refrigerator as a whole can be reduced due to the cold air accumulated in the phase change material 233.

6 is a control block diagram according to another embodiment.

Referring to FIG. 6, a temperature sensor 400 for measuring the temperature inside the storage chamber 2 may be provided. At this time, the temperature measured by the temperature sensor 400 may be transmitted to the controller 300.

Meanwhile, the controller 300 may drive the fan 500 to generate an air flow inside the duct unit 200 or may drive the compressor 600 to generate cold air.

The control unit 300 simultaneously drives the fan 500 and the compressor 600 when the temperature inside the storage chamber 2 measured by the temperature sensor 400 is equal to or lower than the first set temperature, Can be driven.

If the temperature of the storage chamber 2 measured by the temperature sensor 400 is equal to or lower than the second set temperature, the controller 300 does not drive the compressor 600 and drives only the fan 500 It is possible.

The air flow driven by the fan 500 can supply cool air accumulated by the phase change material 233 of the guide unit 230 to the storage chamber 2 through the discharge port 212.

The first set temperature is preferably higher than the second set temperature. The controller 300 drives the fan 500 to cool the storage compartment 2 by the cool air stored in the phase change material 233 when the temperature reaches the second set temperature, have.

At this time, the guide part 230 is heat-exchanged with air discharged into the storage room 2 in the duct part 200, and the storage room 2 is guided by the guide part 230 while the refrigeration cycle is not operated The temperature is lowered.

The duct unit 200 and the storage chamber 2 are communicated with the plurality of discharge ports even if the fan unit 500 is not driven by the control unit 300. Therefore, The material 233 is heat-exchanged with the adjacent air, so that convection may occur with the air contained in the storage chamber 2. [

That is, since the fan 500 is artificially driven to artificially induce convection or naturally convection occurs even if the fan 500 is not artificially driven, the phase change material 233 may cause the convection current to flow into the storage chamber 2, Can be cooled.

On the other hand, when the temperature reaches the first set temperature which is relatively high, the control unit 300 drives the compressor 600 alone or drives the compressor 600 and the fan 500 together, Can be cooled.

In this case, the guide part 230 is heat-exchanged with the cool air discharged into the storage room 2 in the duct part 200, and the cool air supplied to the storage room 2 while the refrigeration cycle is operated, It is possible that the temperature is raised by the heater 230. Since the cool air generated during the operation of the compressor 600 is lower than the temperature of the phase change material 233, the temperature of the cool air can be relatively increased while the phase change material 233 is cooled.

When the compressor (600) is driven, the phase change material (233) can accumulate cold air.

The cool air supplied when the compressor (600) is driven is generally lower than a desired set temperature of the storage chamber (2). Therefore, the temperature difference between the inside of the duct unit 200 and the outside of the duct unit 200 is significantly increased, so that the outside of the duct unit 200, particularly the front surface of the duct cover 210, Lt; / RTI >

However, in the present embodiment, since the cool air passing through the duct unit 200 is heat-exchanged with the phase change material 233, the temperature of the cool air can be raised so that the dew condensation of the duct unit 200 can be prevented have.

It is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

1: cabinet 5: machine room
10: Inner case 20: First door
40: second door 200: duct part
210: duct cover 220: first heat insulating member
230: guide portion 233: phase change material
240: second heat insulating member 300:
400: Temperature sensor 500: Fan
600: Compressor

Claims (12)

A cabinet having a storage compartment;
A duct unit having a plurality of discharge ports for discharging cool air into the storage chamber and providing a path through which cool air is moved;
A guide portion provided in the duct portion and guiding cool air discharged to the storage chamber;
And a compressor for compressing the refrigerant so as to supply cold air to the duct portion,
The guide portion includes a phase change material (PCM)
Wherein the phase change material has a melting point at a temperature lower than a temperature of the storage chamber in which the compressor is set to be driven,
Wherein the guide portion guides cold air to be divided into upper and lower sides of the duct portion. The method according to claim 1,
Wherein the guide portion is heat-exchanged with cool air discharged into the storage chamber in the duct portion, and the cool air provided to the storage chamber while the refrigeration cycle is operated is raised in temperature by the guide portion. The method according to claim 1,
Wherein the guide portion is heat-exchanged with air discharged to the storage chamber in the duct portion, and the temperature of the storage chamber is lowered by the guide portion while the refrigeration cycle is not operated. The method according to claim 1,
The duct portion
A duct cover provided to be exposed to the storage chamber,
A first heat insulating member attached to the rear of the duct cover,
And a second heat insulating member disposed behind the first heat insulating member so as to form a space through which cool air can pass between the first heat insulating member and the second heat insulating member,
And the guide portion is installed between the first heat insulating member and the second heat insulating member. 5. The method of claim 4,
Wherein the guide portion has a tapered portion so that a cross-sectional width of the guide portion increases from the lower portion to the upper portion. 5. The method of claim 4,
The guide portion
Wherein the phase change material comprises a body filled therein,
Wherein the body has a higher thermal conductivity than the phase change material. The method according to claim 6,
Wherein the body is made of HDPE (5200B). The method according to claim 6,
Wherein a guide member is provided at a lower end of the body, the guide member having a predetermined volume without being filled with phase change material. 5. The method of claim 4,
The duct cover is formed with a protrusion,
Wherein the first heat insulating member and the guide portion are respectively formed with through holes through which the protrusions penetrate. The method according to claim 1,
The storage room is a refrigerator room,
Wherein the phase change material has a melting point in the vicinity of zero degrees. The method according to claim 1,
A temperature sensor for sensing the temperature of the storage chamber,
A fan installed in the duct portion,
And a controller for driving the fan when the temperature of the storage room rises to a predetermined temperature or higher. 12. The method of claim 11,
Wherein the discharge port is kept open at all times.

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