KR100377748B1 - The cool-air supplying structure for refrigerators - Google Patents

Abstract

The present invention relates to a refrigerator, and more particularly, to a cold air supply structure of a refrigerator in which a flow path of cold air supplied to a refrigerating chamber is shortened, so that refrigeration efficiency is improved and power consumption is reduced.

The cold air supply structure according to the present invention includes a refrigerator body having a storage space; A heat exchanger for generating cold air for lowering the storage space; Comprising the storage space, the heat exchanger is installed therein, and comprises a cold air outlet for supplying cold air to each storage space, and a barrier formed with a cold air inlet for the cold air circulated through the storage space to the heat exchanger side do.

According to the above configuration, since the evaporator for generating cold air is installed inside the barrier corresponding to the ceiling of the refrigerating compartment, the flow path of the cold air supplied to the refrigerating compartment is shortened and can be lowered within a short time, thereby improving the refrigerating efficiency. The effect of reducing power consumption can be expected.

Description

The cool-air supplying structure for refrigerators}

The present invention relates to a refrigerator, and more particularly, to a structure for supplying cold air to a freezer compartment and a refrigerating compartment, which are storage spaces of a refrigerator.

The refrigerator is a product designed to keep the inside at a low temperature below a predetermined temperature in order to keep food fresh. FIG. 1 shows a general structure of the refrigerator. As shown in the drawing, a refrigerator is generally divided into a freezer compartment F at an upper portion and a refrigerator compartment R at a lower portion thereof by a barrier 1, and is configured to be opened and closed by respective doors 2a and 2b.

A heat exchange chamber C is provided at the rear of the freezing chamber F. An evaporator which generates cold air by heat exchanged with air contacting an outer surface of a low temperature refrigerant flowing therein is provided inside the heat exchange chamber C. 3) is installed.

Looking at the circulation process of the cold air generated by the evaporator (3), as shown by the arrow in Figure 1, a portion of the generated cold air is supplied directly to the freezer compartment (F) by the blowing fan (4), and then circulated, It returns to the evaporator 3 side through the freezer compartment return path 5, and the other part is guided to the lower refrigerating chamber R through the refrigerating chamber supply path 6.

A part of the cold air passing through the refrigerating compartment supply path 6 is supplied to the branch duct 7 to be guided to the front of the refrigerating chamber R, and the other part is supplied to the refrigerating chamber duct 8 installed on the rear wall of the refrigerating chamber R. . The cold air supplied to the refrigerating chamber duct 8 moves downward along the refrigerating chamber duct 8 and is supplied into the refrigerating chamber R through a plurality of cold air discharge holes 8a formed on the front surface thereof.

The cold air supplied to the branch duct 7 and guided forward is supplied to the door duct 9 installed in the refrigerating chamber door 2b. The door duct 9 is installed on the inner side of the refrigerating chamber door 2b, and the cold air supplied to the door duct 9 is similar to the cold air guided to the refrigerating chamber duct 8, and the door duct 9 It descends along and is supplied to the refrigerating chamber (R) through the cold air discharge hole (9a) formed on the front surface of the door duct (9).

The cold air supplied to the refrigerating chamber (R) through this path becomes relatively hot air through heat exchange with the food being stored while circulating the inside of the refrigerating chamber (R). The high temperature air is returned to the evaporator 3 through the refrigerating chamber return environment 10 formed on the rear wall of the refrigerating chamber R, and this process is repeated, thereby lowering the inside of the refrigerator.

Although not shown, a temperature sensing unit is provided at one side of the refrigerating chamber, and when the temperature of the refrigerating chamber R sensed by the temperature sensing unit is lower than a predetermined temperature, such cold air is supplied under the control of a microcomputer (not shown). When the temperature of the refrigerating chamber rises above an appropriate temperature after a certain time, the cold air supply is again performed.

However, the conventional cold air supply structure configured as described above has the following disadvantages.

In the above process, when the cold air generated in the evaporator 3 is supplied to the refrigerating chamber R through the cold air discharge holes 7a and 8a of the refrigerating chamber duct 7 and the door duct 8, considerably. You can see that it takes a long path. That is, the length of the flow path which flows until cold air is supplied to the refrigerating chamber R is long.

As the cold air flows through the long flow path as described above, the kinetic energy is lowered by the flow path resistance such as frictional force generated in the flow process, and the earth output is considerably reached in the refrigerating chamber duct 7 and the door duct 8. It is in a weakened state. In this case, cold air cannot be discharged into the refrigerating chamber R, but flows inside the refrigerator duct 7 and the door duct 8, and as a result, it is considerably lowered to lower the refrigerating chamber R to an appropriate temperature. It takes a long time, which in turn causes a loss in the refrigerating efficiency of the refrigerator and at the same time, it is necessary to continuously supply cold air until the temperature sensed by the above-described temperature sensing unit becomes below a predetermined temperature, thereby increasing power consumption. There is a disadvantage that causes the problem of economics.

An object of the present invention is to improve the problems of the prior art as described above, to provide a cold air supply structure of the refrigerator with improved refrigeration efficiency of the refrigerator.

Another object of the present invention is to provide a cold air supply structure of a refrigerator having reduced power consumption.

1 is a side cross-sectional view showing a cold air supply structure of a conventional refrigerator.

Figure 2 is a side cross-sectional view showing a preferred embodiment of the present invention.

Explanation of symbols for main parts of the drawings

20: refrigerator body 21: barrier

22: evaporator 23: blowing fan

24a: freezer compartment outlet 24b: cold compartment outlet

25a: freezer compartment inlet 25b: cold compartment inlet

26: front discharge port 27: temperature detection unit

30a: freezer door 30b: cold room door

31: door duct 31a: cold air discharge

F: Freezer R: Refrigerator

The cold air supply structure according to the present invention for achieving the above object is a refrigerator body formed with a storage space divided into a freezer compartment and a refrigerating compartment; A heat exchanger for generating cold air for lowering the storage space; And a barrier in which the heat exchanger is partitioned, the cold air supply path through which cold air is supplied to each storage space, and a cold air return path through which cold air circulated through the storage space returns to the heat exchanger. The freezer compartment outlet, which is a cold air supply path for supplying cold air to the freezer compartment, has a larger cross-sectional area than the cold compartment outlet, which is a cold air supply path for supplying cold air to the refrigerating compartment.

According to an embodiment of the present invention, the barrier is provided with a front discharge port for supplying cold air to the door duct.

According to the above configuration, the supply path of the cold air is shortened, so that the output power of the cold air is improved, so that the refrigeration efficiency can be improved and the power consumption can be reduced.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description process, the same freezing compartment and refrigerating compartment as in the prior art will be described with the same reference numerals.

2 shows the structure of a refrigerator according to the present invention. As shown, a storage space is formed in the main body 20 of the refrigerator, and the storage space is partitioned into a freezer compartment F at the upper side and a refrigerating compartment R at the lower side by the barrier 21. In addition, the freezer compartment F and the refrigerating compartment R are configured such that one end thereof is opened and closed by doors 30a and 30b hinged to the refrigerator main body 20.

On the other hand, the inside of the barrier 21 is provided with an evaporator 22 for generating cold air for maintaining the freezing chamber (F) and the refrigerating chamber (R) at a low temperature. The evaporator 22 is a main part constituting a heat exchange cycle together with a compressor (not shown) and a condenser (not shown), and generates cold air by heat-exchanging a low-temperature refrigerant flowing therein with surrounding air. The installation of the evaporator 22 in the barrier 21 as described above is configured to allow the cold air generated by the evaporator 22 to be supplied to the refrigerating chamber R through the shortest path. A rear side of the evaporator 22 is provided with a blowing fan 23 for circulating cold air in the freezing chamber F and the refrigerating chamber R.

Freezer compartment discharge ports 24a and refrigerating chamber discharge ports 24b through which cold air generated in the evaporator 22 is supplied to the freezer compartment F and the refrigerator compartment R are formed on the front and top surfaces of the barrier 21. The freezer compartment discharge port 24a and the refrigerating chamber discharge port 24b have more cold air toward the freezer compartment F in order to generate an appropriate temperature deviation at which the freezer compartment F and the refrigerator compartment R perform their respective functions. The freezer compartment discharge port 24a is large and the refrigerating chamber discharge port 24b is formed to be relatively small so as to be introduced.

And the upper and lower surfaces of the rear portion 21 corresponding to the position of the blowing fan 23 so that the cold air circulated in the freezer compartment (F) and the refrigerating chamber (R) can be returned to the evaporator (22) side of the freezer compartment 25a. And the refrigerator compartment suction port 25b.

In addition, the front of the barrier 21 is formed with a front discharge port 26 for supplying cold air to the door duct 31 installed on the inner surface of the refrigerating chamber door (30b), in the figure the outlet of the front discharge port 26 It is connected directly to the inlet portion of the door duct 31, so that cold air flows into the door duct 31, but when there is a space between the front discharge port 26 and the door duct 31, It is also possible to provide a separate connection duct between the front discharge port 26 and the door duct 31 so that cold air can be supplied.

On the other hand, a temperature sensing unit 27 connected to a microcomputer (not shown) is installed at one side of the refrigerating chamber R, and when the temperature sensed by the temperature sensing unit 27 is less than or equal to a predetermined temperature, the microcomputer is in a heat exchange cycle. By controlling the operation to be stopped, the supply of cold air is stopped, and when the temperature reaches a predetermined temperature or more after a predetermined time, the control is performed so that the cold air is supplied again.

Referring to the drawings the operation of the embodiment of the present invention by the above configuration as follows.

When the refrigerator is operated, cold air is generated in the evaporator 22 installed in the barrier 21. And the cold air is supplied to the freezer compartment F and the freezer compartment R through the freezer compartment outlet 24a and the refrigerator compartment outlet 24b by the blowing force of the blower fan 23, as shown by the arrow in FIG. Will be. In this case, when cold air is supplied to the refrigerating chamber R, the cold air is generated inside the barrier 21 forming the ceiling of the refrigerating chamber F, and also descends through the refrigerating chamber discharge port 24b formed in the barrier 21. Since it is supplied immediately, the refrigerating chamber (R) will be low temperature in a short time.

The refrigerating chamber discharge port 24b is formed to have a smaller size than the freezing chamber discharge port 24a. Therefore, in view of the supply ratio of cold air, a large amount of cold air is supplied to the freezer compartment discharge port 24a, so that the temperature difference of an appropriate level is maintained so that the freezer compartment F and the refrigerator compartment R perform their respective storage functions. It is possible to generate.

On the other hand, a portion of the cold air generated in the evaporator 22 is supplied to the front discharge port 26 flows into the door duct 31, and then descends along the door duct 31 and the door duct 31 Through the plurality of cold air discharge holes (31a) formed on the front side is supplied over the upper and lower refrigerating chamber (R). Therefore, the temperature deviation between the upper and lower parts of the refrigerating chamber R, which may occur due to the supply of cold air from the refrigerating chamber discharge port 24b corresponding to the ceiling part of the refrigerating chamber R, is extended through the door duct 31 up and down the refrigerating chamber R. It can be eliminated by the cold air supplied.

In addition, the cold air supplied to the door duct 31 is supplied to the door duct 31 through a very short path after generation. Therefore, the cold air supplied to the door duct 31 has a sufficient earth output, and is discharged into the refrigerating chamber R without the phenomenon of flowing in the door duct 31, so that the refrigerating chamber R can be opened more quickly. It can be lowered.

The cold air supplied to the freezing compartment F and the refrigerating compartment R through the above process is circulated and heat exchanged with the food being stored, thereby relatively high temperature. The high temperature cold air is returned to the evaporator 22 through the freezer compartment suction port 25a and the refrigerator compartment suction port 25b formed at the rear of the barrier 21, and the freezing chamber F and the refrigerating chamber are repeated as the circulation process is repeated. It keeps (R) at low temperature.

On the other hand, during the cold air circulation process, when the temperature sensed by the temperature sensing unit 27 is less than a predetermined temperature, the microcomputer (not shown) stops the operation of the heat exchange cycle, so that no further cold air is supplied. Done. When the temperature of the refrigerating chamber R rises and the temperature sensed by the temperature sensing unit 27 reaches a predetermined temperature or more, the cold air is circulated by controlling the heat exchange cycle to operate again.

At this time, the refrigerating chamber (R) provided with the temperature sensing unit 27 is lowered to a predetermined temperature or less within a faster time as compared with the conventional, as can be seen in the above-described cold air circulation process. This means that even if the heat exchange cycle is operated for a short time, sufficient refrigeration capacity can be secured, and as a result, the power consumption will be reduced by the shortened time.

As described above, the refrigerator according to the present invention is configured to shorten the flow path of the cold air supplied to the refrigerating chamber by installing an evaporator generating cold air inside the barrier corresponding to the ceiling of the refrigerating chamber. Therefore, the refrigerating compartment can be sufficiently low in a short time, thereby improving the refrigerating efficiency of the refrigerating compartment, and reducing the power consumption, thereby improving economic efficiency, thereby providing a feeling of confidence in the product. .

Claims (3)

A refrigerator body having a storage space divided into a freezer compartment and a refrigerating compartment; A heat exchanger for generating cold air for lowering the storage space; And a barrier in which the heat exchanger is partitioned, the cold air supply path through which cold air is supplied to each storage space, and a cold air return path through which cold air circulated through the storage space returns to the heat exchanger. Configured by And a freezer compartment outlet, which is a cold air supply path for supplying cold air to the freezer compartment, having a larger cross-sectional area than a cold compartment outlet, which is a cold air supply path for supplying cold air to the refrigerator compartment. delete The refrigerator's cold air supply structure according to claim 1, wherein the barrier is provided with a front discharge port for supplying cold air to the door duct.