KR20170100756A - A Refrigerator - Google Patents

Abstract

The present invention relates to a bottom freezer refrigerator in which an ice making chamber is formed in a door and, more specifically, relates to a refrigerator, wherein cold air formed in an independent space of cold storage is individually guided to the ice making chamber and the cold storage to reduce power consumption and noise generated by a lengthened flow path, and to keep each food in a clean state in the cold storage or a freezer. Moreover, food in the cold storage can be freshly kept in a high humidity state, and the door is not forcibly opened.

Description

A Refrigerator

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a bottom freezer refrigerator having an ice making chamber formed in a door, and more specifically, cold air formed by an evaporator installed in an independent refrigerating chamber is individually guided to an ice making chamber of a door,

The present invention relates to a refrigerator capable of minimizing power consumption and noise and maintaining a clean state, and also capable of storing food in a refrigerator room in a high humidity state, preventing a door from being opened forcibly, and sufficiently securing a built- .

Generally, a refrigerator is a device intended for low temperature storage of food. It is a household appliance that is frozen or refrigerated according to the condition of the food to be stored. Currently, the refrigerator is variously changed .

That is, an inner portion made of a polygon is formed inside the body, and a partition wall separating the upper and lower spaces is provided in the inner portion

A freezing chamber is formed in the upper portion and a freezing chamber is formed in the lower portion,

A plurality of doors are rotatably coupled to the front surface,

A bottom freezer refrigerator which can easily take out and use the food stored in the refrigerator without requiring the user to bend the waist has appeared,

According to the embodiment, the refrigerator in which the ice making facility is built on the door of the refrigerator compartment also appears.

However, in such a refrigerator, the evaporator of the freezer compartment located at the lower part generates cold air by the heat exchange method, and moves to the inside of the ice compartment along the flow path to generate ice. At this time, the cold air inside the ice compartment is transferred to the refrigerating compartment, Keep the goods at low temperature. And the cold air in the refrigerating chamber is moved back to the freezing chamber to repeatedly circulate the ice-making chamber, the refrigerating chamber, and the freezing chamber.

Therefore, in the conventional bottom freezer refrigerator, the length of the flow path for moving the freezing chamber, the ice-making chamber, and the refrigerating chamber becomes long,

Particularly, as the length of the flow path through which cool air travels becomes longer, the power consumed due to the operation of the motor and the heat loss for maintaining the increased power is inevitably increased.

In addition, in the conventional refrigerator, the refrigerating chamber located at the upper portion has to be in a state of sufficient moisture to maintain fresh state, and conversely, when the freezing chamber has a lot of moisture, You have to give. However, in the conventional refrigerator, the cold air in the high-humidity state of the refrigerating chamber moves to the freezing chamber, and malaria is generated on the inner side. On the other hand, the cold air in the dry freezing chamber moves to the refrigerating chamber through the ice making chamber, There was a problem that the freshness of the food dropped.

Furthermore, the conventional bottom freezer refrigerator circulates between the refrigerator compartment and the freezer compartment in which doors with different cool air are installed, and the refrigerator compartment and the freezer compartment communicate with each other. Accordingly, when the door of the refrigerator room located at the upper side is tightly closed, air is introduced into the inside of the refrigerator compartment, and the inflow air is forced to open through the refrigerator compartment and into the freezer compartment.

In addition, as the cold air moves between the freezer compartment and the ice-making compartment and the refrigerating compartment, there is a problem that the smell of food stored in the refrigerating compartment or the freezing compartment spreads throughout the refrigerator.

In addition, although the dispenser is formed on the door when the ice making facility is constructed, the ice making room is installed in a state in which a separate space is provided inside the refrigerating chamber, so that the built-in space is narrowed.

KR 10-2005-0127516 A1 KR 10-2005-0008905 A1

Accordingly, it is an object of the present invention to solve the problem that the cool air generated inside the freezing chamber by the evaporator keeps a long length of the circulation path repeatedly circulating between the freezing chamber and the ice making chamber.

That is, the present invention aims to minimize the power consumption and noise generated while keeping the length of the flow path of the cool air moving between the freezing chamber, the ice-making chamber, and the refrigerating chamber long.

In addition, the refrigerating chamber maintains a sufficient high-humidity state for a long time, and conversely, the freezing chamber maintains a dry state so as to prevent sexual exploitation.

In addition, the present invention is intended to keep the refrigerating chamber, the freezing chamber and the ice making chamber in a clean state so that the smell of food does not spread throughout the refrigerator.

In addition, the present invention aims at minimizing the work of opening the door forcibly and the narrowing of the internal space of the internal chamber due to the ice making chamber.

To this end, the present invention provides a refrigerator comprising: a refrigerating chamber and an evaporator formed at an upper portion thereof;

A freezing chamber and a third evaporator formed at a lower portion thereof;

At least one door rotatably installed in the refrigerator compartment and the freezer compartment;

An ice making chamber installed in the door;

A cold air inflow / outflow duct which is installed in the refrigerating compartment at an inner side or an outer side in a longitudinal direction and the other end of which is exposed in an inner wall of the refrigerating compartment;

A connecting port provided at one side of the ice making chamber of the door to be in close contact with the other end of the cold air inflow / outflow duct when closed;

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In the refrigerating chamber, an evaporator is provided, and a separate cold forming portion is formed inside the refrigerating chamber. The cool air generated inside the cold forming portion is guided to the ice making chamber of the door through the cool air inflow and outflow duct and the connecting port by heat exchange during operation of the evaporator .

In the present invention, a third evaporator is installed in the freezer compartment, and an evaporator or a first evaporator and a second evaporator are installed in the refrigerating compartment,

As the cold air generated in each independent space is supplied to each ice maker, the freezer compartment and the refrigerating compartment,

By shortening the length of cold air flow path and reducing power consumption and noise,

At the same time, the refrigerator room is maintained in a sufficiently high humidified state to allow fresh food to be refrigerated, and the freezer room can be kept dry to minimize the incidence of sexual exploitation,

It is possible to keep the refrigerator compartment, the freezer compartment, and the ice-making compartment clean, by preventing the damage caused by the smell movement of the food,

It is possible to prevent the freezing chamber door of the other side from being forcibly opened when the refrigeration chamber door of one side is closed.

In addition, in the present invention, the ice making room is installed on the door, so that the built-in space of the refrigerator can be sufficiently secured.

1 and 2 are perspective views of a door of a refrigerator according to an embodiment of the present invention.
Fig. 3 is an explanatory view showing the state of use of the door according to the embodiment of the present invention
FIG. 4 to FIG. 6 are diagrams showing the state of use of the refrigerator according to the embodiment of the present invention,
FIG. 7 is a circuit diagram briefly showing a configuration of a refrigerator according to an embodiment of the present invention; FIG.

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

1 and 2 illustrate a door of a refrigerator when the door is opened and a door when the door is closed according to an embodiment of the present invention.

As shown in the drawings, the refrigerator of the present invention has an interior portion formed inside a polygonal body 1, and a partition wall separating upper and lower spaces is provided in the interior portion, and a refrigerator compartment 10, (20).

At this time, the refrigerator compartment 10 is formed in the upper part of the refrigerator compartment 10, and a shelf for efficiently storing various kinds of food items is installed in the refrigerator compartment 10 to divide the space of the refrigerator compartment 10, Not only can be adjusted in height, but also can be freely installed / removed.

An evaporator 11 is provided at the rear of the refrigerating chamber 10 and a cold forming portion 12 is formed at an inner side of the refrigerating chamber 10 so that the cold air is cooled by the heat exchanging method during operation of the evaporator 11, Respectively.

The cold cool air generated at this time flows into the refrigerator compartment 10 to store the food in the refrigerator and some of the cool air flows into and out of the ice making compartment 33 of the door along the cool air inflow and outflow duct 40, It can be stored frozen.

At this time, the cool air forming unit 12 is divided into a first cool air forming unit 12a and a second cool air forming unit 12b,

The cool air generated inside the first cool air forming portion 12a is guided to the inside of the refrigerating chamber 10 to lower the temperature of the refrigerating chamber 10 and the cool air generated inside the second cool air forming portion is guided to the ice making chamber of the door, Can be generated and stored frozen.

In this embodiment, the first evaporator 11a is divided into the first evaporator 11a and the second evaporator 11b, and the first evaporator 11a and the second evaporator 11b, And can be installed in the portion 12b.

The cool air discharge duct 40 is fixedly installed on the wall surface of the refrigerating compartment 10 in a protruded state. The cool air inflow duct is connected to the cool air forming unit 12 at one side And the other end where the through-hole is formed is installed in a state exposed to the inside of the refrigerating chamber (10).

When the door is closed, the other end 41 of the cool air inflow / outflow duct 40 and the outflow inlet 31 of the door 30 are connected to each other So that cold air can flow into or out of the ice making chamber 33 along the cold air outlet duct 40.

A temperature sensor 34 is installed around the outflow inlet 31. When the door 30 is opened, the other end 41 of the cold air inflow / outflow duct 40 and the outlet It is confirmed that the inlets 31 are separated from each other, so that the motor or the damper can be automatically controlled to control the movement of the cold air.

The cool air inflow / outflow duct 40 may be provided in a state protruding from the inside of the refrigerating compartment, or may be provided so as to expose only the other end inside the wall surface.

In addition, the cold air inflow / outflow duct 40 may be formed such that a longitudinal partition wall is formed on the inside of an enclosure so that cool air is introduced into one side and air is blown out from the other side,

A cold air inflow duct 40a for transferring cold air from the cold air forming unit 12 to the inside of the ice making chamber and a cold air outflow duct 40b for transferring cold air from the ice making chamber to the cold air forming unit of the refrigerating chamber 10 And an inlet port and an outlet port may be formed on the side or rear surface of the door 30 corresponding thereto.

The cold air inflow duct 40 or the cold air inflow duct 40a and the cold air outflow duct 40b are installed at the shortest distance between the ice making chamber and the cool air forming unit in order to minimize the length of the flow path through which cool air flows.

The doors 30a and 30b are rotatably installed on the front left and right sides of the refrigerator compartment 10 so as to open or close the front of the opened refrigerator compartment 10 in whole or in part.

A freezing chamber 20 is formed in the lower portion of the refrigerating chamber 10 and a shelf for efficiently storing food to be refrigerated and stored is formed inside the freezing chamber 20. And a separate freezer compartment door 30c for shielding the opened internal space is rotatably installed.

A third evaporator 21 is installed in the rear of the freezer compartment 20 and the third evaporator 21 generates cold air in the third freezer compartment 22 inside the freezer compartment 20 in a heat- And the cold air generated by the third evaporator 21 flows inward into the freezing chamber 20 where the shelf is installed to freeze and store the food stored in the freezing chamber 20.

Therefore, in the present invention, the third evaporator 21 is installed in the freezer compartment 20, and the evaporator 11 or the first evaporator 11a and the second evaporator 11b are installed in the refrigerating compartment 10, The cold air generated in the independent space of the refrigerator compartment 20 is supplied to the freezing compartment 20 and the refrigerating compartment 10,

It is possible to solve the problem that the power consumption and the noise are increased while ensuring a sufficient built-in space, the damage caused by the movement of food odor, and the problem that the door is forcibly opened.

In addition, the inside of the refrigerating chamber can be kept in a high humidity state and fresh food can be stored, and the freezing chamber can be maintained in a dry condition, thereby preventing malnutrition.

3 is a view illustrating a connector that operates according to whether a door of a refrigerator is opened or closed according to an embodiment of the present invention.

The connecting port 32 is formed in the outflow inlet 31 of the door 30. The connecting port 32 is formed in an annular shape fixed to the outflow opening of the door or a pair of outflow openings and the rim of the inlet. And includes a mounting portion 32a and a flexible elastic body 32b curved upwardly above the mounting portion.

When the door is closed, the elastic body 32b having a volume feeling is contracted while the other end 41 of the refrigerant outflow pressure duct 40 is in close contact with the outlet 32, The distance between the door and the refrigerating chamber 10 is increased by the distance between the door and the refrigerating chamber 10 so as to be completely close to each other.

Accordingly, the ice making chamber 33 of the door 30, which is separated by the connecting port 32 mounted on the outlet port or a pair of the outlet port and the inlet port, is connected to the cold outlet pressure duct of the refrigerating chamber 10 ,

It is not necessary to provide a space in which a separate ice making room is installed inside the refrigerating chamber, so that a sufficient built-in space can be secured.

4 and FIG. 4A illustrate how cool air circulates in a refrigerator according to an embodiment of the present invention.

Referring to FIG. 1, a refrigerator according to an embodiment of the present invention includes a refrigerating chamber 10 formed at an upper portion thereof, a cold forming portion 12 formed at an inner side thereof, and an evaporator 11 installed at the cold forming portion .

At this time, a plurality of flow paths 15 for supplying cool air to the inside of the refrigerating chamber 10 are formed in the cold forming part 12, and a first fan (not shown) for controlling the amount of cool air flowing into / 13, and a first damper 14 is provided for on / off interlocking of the cool air to the outside of the flow channel.

The cool air forming unit 12 is connected to the cool air inflow and outflow duct 40 and may be provided with a second damper 19 for on / off interlocking of cool air flowing in and out of the cool air inflow and outflow duct.

Accordingly, in the present invention, the cold air generated inside the cold air forming portion 12 flows into the refrigerating chamber 10 through the flow path 15 during the intermittent operation of the first damper 14, and when the second damper 19 is interrupted, And the cool air generated inside the forming portion can flow in and out into the ice making chamber 33 provided in the door 30 through the cold air inflow and outflow duct 40.

A freezing chamber 20 is formed in a lower portion of the refrigerating chamber 10 and a separate third cold forming portion 22 is formed inside the freezing chamber 20, An evaporator 21 is installed

A plurality of freezing chamber flow passages 20 for supplying cold air to the inside of the refrigerating chamber 10 are formed in the third freezing chamber forming portion 22. The amount of cool air flowing in and out of the freezing chamber 20, And a third damper 24 for on / off interlocking of the cooling / heating operation.

5 and 5A illustrate how the cold air circulates in the refrigerator according to the second embodiment.

Referring to FIG. 1, a refrigerating chamber 10 is formed in an upper portion, and a first cold forming portion 12a and a second cold forming portion 12b are formed separately from each other. The first evaporator 11a and the second evaporator 11b may be installed in the first cold air forming portion 12a and the second cold air forming portion 12b, respectively.

A plurality of flow paths 15 for supplying cool air to the inside of the refrigerating chamber 10 are formed in the first cool air forming portion 12a and a plurality of flow paths 15 for controlling the amount of cool air flowing into / A fan 13 may be installed. In this embodiment, a first damper 14 may be provided for on / off interlocking of cold / hot air.

The second cool air forming unit 12b may be provided with a second damper 19 connected to the cool air inflow and outflow duct 40 for on / off interlocking of cool air flowing in and out of the cool air inflow and outflow duct. At this time, the second damper 19 is installed inside the ice making chamber according to the embodiment so that the cool air is drawn into the ice making chamber.

Accordingly, in the present invention, the cool air generated inside the first cool air forming portion 12a flows into the inside of the refrigerating chamber 10, and the cool air generated inside the second cool air forming portion 12a is installed in the door through the cool air inflow and outflow duct And is introduced into / out of the ice making chamber 33,

It is possible to solve the problem that the power consumption and the noise are increased while ensuring a sufficient built-in space, the damage due to the moving of the food odor, and the problem that the door is forcibly opened.

In addition, the inside of the refrigerating chamber can be kept in a high humidity state and fresh food can be stored, and the freezing chamber can be maintained in a dry condition, thereby preventing malnutrition.

A freezing chamber 20 is formed in the lower portion of the refrigerating chamber 10 and a separate third cold forming portion is formed inside the freezing chamber 20. The third cold forming portion 22 is provided with a third evaporator (21) is provided. A plurality of freezing chamber flow passages 20 for supplying cold air to the inside of the refrigerating chamber 10 are formed in the third freezing chamber forming portion 22. The amount of cool air flowing in and out of the freezing chamber 20, And a third damper 24 for on / off interlocking of the cooling / heating operation.

6 is a schematic view illustrating a configuration for circulating cold air in the refrigerating compartment 10 according to an embodiment of the present invention,

Referring to FIG. 1, a separate first cold forming portion 12a and a second cold forming portion 12b are formed inside the refrigerating chamber 10, and one The evaporator 11 may be installed in a shared state.

At this time, not only the area of the first cool air forming part 11a and that of the second cool air forming part 11b are different from each other, but also the areas sharing the evaporator are also different from each other and are formed inside the first cool air forming part and the second cool air forming part Are different from each other and are heat-treated.

A plurality of flow paths 15 for supplying cold air to the inside of the refrigerating chamber 10 are formed in the first cold air forming part 12a and a plurality of flow paths 15 for controlling the amount of cool air flowing in / 1 fan 13, and in some embodiments, a first damper 14 may be provided for on / off interlocking of cold / hot air.

A second damper 19 connected to the cold air inflow and outflow duct 40 for on / off interlocking of the cold air moving in the cold air inflow and outflow duct 40, And a second fan 18 for reducing the cooling rate is formed. The second damper or the second fan formed at this time may be installed inside the ice making chamber 33 according to the embodiment.

Accordingly, in the present invention, the cold air generated in the first and second cold air forming units in the different regions by one evaporator flows into / out of each of the refrigerating chamber 10 and the ice making chamber 33

It is possible to solve the problem that the power consumption and the noise are increased while ensuring a sufficient built-in space, the damage caused by the movement of food odor, and the problem that the door is forcibly opened.

In addition, the inside of the refrigerating chamber can be maintained in a high-humidity state and fresh food can be stored, and the freezing chamber can be maintained in a dry state,

As shown in FIG. 6A, according to an embodiment of the present invention, the second cool air forming portion 12b and the second cool air forming portion 12a are provided with a second coolant flow path that can move cool air from one side to the other, (16)

A fourth damper 17 capable of interrupting cool air that can flow in and out through the second flow path 16 is formed,

The first cool air forming portion 12a secures further expanded cool air by the second cool air forming portion 12b during the operation of the fourth damper 17 or the second cool air forming portion 12b protects the first cool air The cooling air expanded by the forming portion 12a can be secured and the temperature of the refrigerating chamber 10 or the ice making chamber 33 can be rapidly cooled or the temperature can be adjusted.

7 to 7B are flowcharts illustrating a configuration of a refrigerator according to an embodiment of the present invention.

In the present invention, one side of a compressor is connected to an evaporator of an ice making chamber, and the other side is connected to a condenser. The other end of the condenser is connected in series with the dryer

The other side of the dryer is connected to the valve VAL_VE and the valve VAL_VE is connected to the capillary R_CAPILLARY of the freezing compartment 10 and the capillary R_CAPILLARY of the freezing compartment 20 is connected to the valve 1 evaporator (R_EVA).

At this time, the other side of the first evaporator (R_EVA) is connected to the third evaporator (F_EVA) and the third evaporator (F_EVA) is connected in series with the second evaporator (I / M_EVA) The other side of the second evaporator (I / M_EVA) is connected to a compressor.

At this time, a capillary (F_CAPILLARY) of the freezer compartment 20 may be connected in parallel between the valve VAL_VE and the third evaporator F_EVA,

According to the embodiment, the capillary (F_CAPILLARY) and the third evaporator (F_EVA) of the freezing chamber connected in series may be connected in parallel between the valve VAL_VE and the second evaporator I / M_EVA.

In the embodiment, in a state where the capillary (F_CAPILLARY) of the freezing chamber and the third evaporator (F_EVA) of the freezing chamber connected in series are connected in parallel between the valve and the compressor,

The capillary (R_CAPILLARY) of the refrigerating chamber connected in series between the valve and the compressor and the first evaporator (R_EVA) are connected in parallel,

In addition, a capillary (I / M_CAPILLARY) of the ice making chamber connected in series between the valve and the compressor and a second evaporator (I / M_EVA) are connected in parallel,

Each of the evaporators may be separately operated so that the cold air generated by the second evaporator (I / M_EVA) of the refrigerating chamber is applied to the inside of the ice making chamber.

Accordingly, in the present invention, the third evaporator is installed in the freezer compartment, and the evaporator, the first evaporator and the second evaporator are installed in the refrigerating compartment, and the cool air generated in each independent space is supplied to the respective ice- In addition,

The length of the cold air flow path is shortened so that consumption can reduce power and noise,

In addition, the refrigerator can be kept in a high humidity state to store fresh food in the refrigerator,

It is possible to keep the food and ice contained in each of the refrigerator compartment, the freezer compartment and the ice-making compartment cleanly,

It is possible to prevent the freezing chamber door of the other side from being forcibly opened when the refrigeration chamber door of one side is closed.

1: Body 10: Refrigerator
11: an evaporator 11a: a first evaporator
11b: second evaporator 12: cold air forming part
12a: first cold air forming part 12b: first cold air forming part
13: First fan
14: first damper 15:
16 second flow path 17: fourth damper
18: second fan 19: second damper
20: Freezer
21: third evaporator 22: third cold air forming part
23: third fan 24: third damper
30: Door 31: Outlet entrance
32: Connecting port 32a:
32b: elastic body 33: ice making chamber
40: Cold air inflow / outflow duct
41: other end

Claims (9)

A refrigerating chamber and an evaporator formed on the upper portion;
A freezing chamber and a third evaporator formed at a lower portion thereof;
At least one door rotatably installed in the refrigerator compartment and the freezer compartment;
An ice making chamber formed in the door;
A cold air inflow / outflow duct which is installed in the refrigerating compartment at an inner side or an outer side in a longitudinal direction and the other end of which is exposed in an inner wall of the refrigerating compartment;
A connecting port provided at one side of the ice making chamber of the door to be in close contact with the other end of the cold air inflow / outflow duct when closed;
,
In the refrigerating chamber, an evaporator is provided, and a separate cold forming portion is formed inside the refrigerating chamber. The cool air generated inside the cold forming portion is guided to the ice making chamber of the door through the cool air inflow and outflow duct and the connecting port by heat exchange during operation of the evaporator . The method according to claim 1,
The cold air generating unit of the refrigerating compartment is divided into a first cold air forming unit and a second cold air forming unit. The cold air generated inside the first cold air forming unit is guided to the inside of the refrigerating chamber through the flow path, And the generated cold air is guided to the ice-making chamber of the door through the cold air inflow and outflow duct. 3. The method of claim 2,
Wherein the first cold air forming part and the second cold air forming part share one evaporator. 3. The method of claim 2,
Wherein the evaporator is divided into a first evaporator and a second evaporator, and the first evaporator and the second evaporator are installed in the first cold air forming unit and the second cold air forming unit, respectively, The method according to claim 1,
And a temperature sensor is installed at the other end of the cool air inflow / outflow duct or around the connection port to control the cool air flowing out while sensing the opening and closing of the door. The method according to claim 1,
Wherein the connecting port includes an annular mounting portion fixed to an outlet of the door or a pair of outlets and an inlet, and a soft elastic body curved upwardly above the mounting portion, The method according to claim 1,
The cool air forming portion is provided with a fan for controlling the amount of cool air or cooling rate moving in and out of the flow path and a first damper for on / off interrupting the cool air moving out of the flow path,
A second fan for controlling the amount of cool air moving to the ice-making chamber through the cool air inflow / outflow duct or a cooling rate thereof, and a second damper for on / off interrupting the cold air moving to the ice-making chamber through the cool air inflow- Refrigerator for 3. The method of claim 2,
The first cool air forming unit is provided with a first fan for controlling the amount of cool air or cooling rate moving along the flow path and a first damper for on / off interrupting the cool air moving out of the flow path,
A second fan for controlling an amount or a cooling rate of the cold air moving along the cold air inflow and outflow duct and a second damper for on / off interrupting the cold air moving to the ice-making chamber through the cold air inflow and outflow duct And a refrigerator 9. The method of claim 8,
A second flow path is formed between the second cool air forming section and the first cool air forming section and a fourth damper capable of interrupting cool air that can flow in and out through the second flow path,
The first cold air forming portion secures the cold air further expanded by the second cold air forming portion during the fourth damper operation or the second cold air forming portion secures the cold air extended by the first cold air forming portion Features a refrigerator

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