KR20020078670A - A cooling air circulation structure for refrigerator - Google Patents

Abstract

PURPOSE: A structure for circulation of chilled air of refrigerator is provided to reduce deviation of temperature in a refrigerator compartment to the minimum. CONSTITUTION: A structure includes a heat exchanger, an evaporator(39), generating chilled air; chilled air passages delivering the chilled air generated by the heat exchanger to storage spaces, a freezer compartment(33) and a refrigerator compartment(35), and including a plurality of outlets in the freezer compartment and a refrigerator compartment duct(46); chilled air return passages returning the chilled air having circulated in the storage spaces to the heat exchanger and including a freezer compartment return passage(48) and a refrigerator compartment return passage(49); and a chilled air regenerating device taking in chilled air from one side in the storage spaces to the other side in the storage spaces and including a regenerating duct(50) and a regenerating fan(52).

Description

A cooling air circulation structure for refrigerator

The present invention relates to a refrigerator, and more particularly, to a cold air circulation structure of the refrigerator to allow the temperature distribution of the entire inside of the refrigerator compartment to be even.

1 illustrates a cold air circulation structure of a refrigerator according to the prior art. As shown in the drawing, the freezer compartment 3 and the refrigerating compartment 5, which are storage spaces, are separately partitioned by the barrier 4 in the refrigerator body 1.

A plurality of shelves 5 'are installed in the refrigerating chamber 5 to place a stock on each shelf 5'. In the lowermost part of the refrigerating compartment 5, a vegetable compartment 6 for storing vegetables or fruits is formed separately. In general, the vegetable compartment 6 is configured in a drawer type.

The freezing chamber 3 and the refrigerating chamber 5 are opened and closed by doors 7 and 7 ', respectively, and communicate with the outside. A door basket 8 is also provided on the inner surfaces of the doors 7 and 7 ′ to store the stored matter.

On the other hand, the evaporator 9, which is a component of the heat exchange cycle that generates cold air circulated inside the refrigerator, is installed at the rear of the freezer compartment 3. The space in which the evaporator 9 is installed is shielded by the shroud 10, and the grill pan 12 is installed between the shroud 10 and the freezing chamber 3. And a blower fan 14 is installed on top of the evaporator 9 to circulate the cold air generated by the evaporator 9. The blowing fan 14 transmits cold air between the shroud 10 and the grill pan 12. And the grill pan 12 is provided with a discharge port (not shown) for discharging the cold air to the freezing chamber (3).

The cold air dropped through the shroud 10 and the grill pan 12 is supplied to the refrigerating chamber 5 through the barrier 4. To this end, the refrigerating chamber duct 16 is provided at the rear of the refrigerating chamber 5 to extend from the top to the bottom. The refrigeration chamber duct 16 is provided with a plurality of cold air discharge ports 17 for discharging cold air into spaces partitioned by the shelves 5 ', respectively.

Next, the freezer compartment return path 18 is formed to communicate with the space where the evaporator 9 is installed through the upper surface of the barrier 4 corresponding to the bottom of the freezer compartment 3. The cold air circulating in the freezer compartment 3 is returned to the evaporator 9 through the freezer compartment return passage 18. The refrigerator compartment return passage 19 is formed to communicate with the space where the evaporator 9 is installed through the lower surface of the barrier 4 corresponding to the ceiling of the refrigerator compartment 5.

It will be described that the cold air is circulated in the refrigerator according to the prior art having such a configuration.

When the refrigeration cycle is operated, a relatively low temperature refrigerant is supplied to the evaporator 9 to exchange heat with air passing through the evaporator 9. The heat-exchanged air is supplied to the freezing compartment 3 and the refrigerating compartment 5 by the blowing fan 14.

That is, some of the cold air transmitted to the space between the shroud 10 and the grill pan 12 by the blower fan 14 is transferred to the freezing chamber 3 through the discharge port of the grill pan 12. The remaining air falls to the lower portion of the space and is delivered to the refrigerating chamber duct 16.

First, the cold air supplied to the freezer compartment 3 maintains the inside of the freezer compartment 3 at a predetermined temperature while circulating the inside of the freezer compartment 3 and is returned to the evaporator 9 through the freezer compartment return passage 18. . Then, after the heat exchange in the evaporator (9) is circulated by the blower fan (14).

The cold air supplied to the refrigerating chamber 5 is supplied onto each shelf 5 'through the refrigerating chamber duct 16. The cold air supplied to the refrigerating compartment 5 is circulated through the refrigerating compartment 5 and then returned to the evaporator 9 through the refrigerating compartment return passage 19. The cold air returned as described above is circulated again in the refrigerator after the heat exchange in the evaporator 9.

However, the conventional cold air circulation structure having the configuration as described above has the following problems.

In the conventional cold air circulation structure, the blower fan 14 is driven while the refrigeration cycle is operated, and thus, the cold air circulating in the refrigerating compartment is transferred to the evaporator 9 through the refrigerating compartment return passage 19 to exchange heat, and then to the refrigerator again. It will cycle inside. Therefore, the temperature inside the refrigerating chamber 5 is different depending on the on and off of the compressor constituting the refrigeration cycle as shown in FIG. That is, when the compressor is turned on and the temperature is increased, that is, when a refrigeration cycle is operated, a lot of cold air is delivered to the refrigerating chamber 5 so that the temperature is relatively low, and when the refrigeration cycle is stopped, the temperature is lowered. At this time, the temperature of the refrigerating chamber (5) shows a lot of deviation depending on the operation of the refrigeration cycle has a problem of reducing the freshness of the storage.

In the conventional cold air circulation structure, the cold air discharged to the refrigerating compartment is about −10 to about −9 ° C., and the cold air returned through the refrigerating compartment return passage 19 is about 0 to about 2 ° C. Therefore, there is also a problem in that the cold air is returned to a relatively low temperature a lot of heat loss occurs.

Therefore, an object of the present invention is to solve the problems of the prior art as described above, to minimize the temperature deviation of the refrigerating chamber.

Another object of the present invention is to minimize the heat loss of the cold air generated in the refrigerating chamber.

1 is a cross-sectional view showing a cold air circulation structure of a refrigerator according to the prior art.

Figure 2 is a cross-sectional view showing the configuration of a preferred embodiment of the cold air circulation structure of the refrigerator according to the present invention.

Figure 3 is a view in the direction A of Figure 2 showing the configuration of an embodiment of the present invention.

Figure 4 is a graph showing the refrigerator compartment temperature according to the temperature of the compressor in the cold air circulation structure according to the present invention.

Explanation of symbols on the main parts of the drawings

30: refrigerator body 33: freezer

34: Barrier 35: Cold Room

35 ': Shelf 36: Vegetable Room

37,37 ': Door 38: Door basket

39: evaporator 40: shroud

42: grill pan 44: blowing fan

46: refrigerating chamber duct 47: discharge port

47 ': Regeneration inlet 50: Regeneration duct

52: playback fan 54: playback discharge outlet

According to a feature of the present invention for achieving the object as described above, the present invention provides a heat exchanger for generating cold air, a cold air supply passage for transferring the cold air generated in the heat exchanger to the storage space, and circulating the storage space And a cold air return passage for returning cold air to the heat exchanger, and cold air regeneration means for sucking cold air from one side of the storage space and discharging it to the other side of the storage space.

The cold air regeneration means includes a regeneration fan for sucking cold air from one side of the refrigerating chamber and a regeneration duct for transferring cold air sucked by the regeneration fan to the other side of the refrigerating chamber.

The regeneration duct is provided inside the cold air supply passage, and the discharge port is configured to coincide with the discharge port of the cold air supply passage.

The cold air regeneration fan is located at a lower side of the refrigerating chamber to recycle cold air at the bottom of the refrigerating chamber to the upper portion.

According to the present invention having such a configuration, since the cold air delivered to the refrigerating compartment can be recycled and used, the temperature of the whole refrigerating compartment becomes relatively uniform, and there is an advantage that the heat loss of the cold air is minimized.

Hereinafter, a preferred embodiment of the cold air circulation structure of the refrigerator according to the present invention as described above will be described in detail with reference to the accompanying drawings.

2 and 3, the refrigerator body 30 includes a freezing compartment 33 and a refrigerating compartment 35, which are storage spaces. The freezing compartment 33 and the refrigerating compartment 35 are divided by the barrier 34 so that the refrigerating compartment 35 is formed at the lower portion of the freezing compartment 33 at the top.

A plurality of shelves 35 ′ are installed in the refrigerating chamber 35 so that the storage is placed on the upper surface thereof. And the lower side of the refrigerating chamber 35 is provided with a separate vegetable compartment 36 for storing vegetables or fruits.

The freezing chamber 33 and the refrigerating chamber 35 are selectively communicated with the outside by doors 37 and 37 ', respectively. In addition, a plurality of door baskets 38 are installed on the inner surfaces of the doors 37 and 37 'to store the stored matter.

Meanwhile, an evaporator 39, which is a heat exchanger constituting a refrigeration cycle, is installed at the rear end of the freezing chamber 33 to generate cold air. The shroud 40 and the grill pan 42 are partitioned between the evaporator 39 and the freezing chamber 33. The space between the shroud 40 and the grill pan 42 serves to distribute cold air to the freezing chamber 33 and the refrigerating chamber 35. Here, the grill fan 42 has a plurality of discharge ports (not shown) for supplying cold air to the freezing compartment 33. The blower fan 44 provides a driving force for cooling air to flow inside the refrigerator at an upper portion of the evaporator 39. ) Is installed.

A refrigeration chamber duct 46 is provided at the rear of the refrigerating chamber 35 to supply cold air into the refrigerating chamber 35. The refrigerating chamber duct 46 extends from the upper end to the lower end of the refrigerating chamber and has a discharge port 47 corresponding to each shelf 35 '. Cold air is delivered to the vegetable compartment 36 through the refrigeration chamber duct 46. A regeneration suction port 47 ′ is formed at a lower end of the refrigerating chamber duct 46 to communicate the regeneration duct 50 to be described below with the refrigerating chamber 35.

In addition, a freezer compartment return passage 48 is formed through the inside of the barrier 34 to return the cold air circulated inside the freezer compartment 33 to the evaporator 39. In addition, the refrigerating chamber return passage 49 is formed through the inside of the barrier 34 to return the cold air circulated inside the refrigerating chamber 35 to the evaporator 39.

Meanwhile, a regeneration duct 50 is provided to smoothly circulate the cold air inside the refrigerating chamber 35. In the present embodiment, the regeneration duct 50 is installed inside the refrigerating chamber duct 46, but is not necessarily the same, and may be installed at both sides of the refrigerating chamber 35 or at a position separate from the refrigerating chamber duct 46. have.

The regeneration fan 52 is installed at the lower end of the regeneration duct 50. The lower end of the regeneration duct 50 is fitted to the regeneration suction opening 47 ′ of the refrigerating chamber duct 46. Therefore, the regeneration fan 52 is positioned inside the regeneration suction opening 47 ′ to suck the cold air in the refrigerating chamber 35.

The regeneration duct 50 is installed vertically long in the refrigerating chamber duct 46, and the regeneration discharge holes 54 'are formed at positions corresponding to the discharge holes 47 formed in the refrigerating chamber duct 46, respectively. The regeneration discharge port 54 ′ is formed at a position corresponding to the discharge port 47 so that the cool air flowing through the regeneration duct 50 may be supplied to the refrigerating chamber 35 through the discharge port 47 again. At this time, the outlet cross-sectional area of the regeneration discharge port 54 'is preferably smaller than the outlet cross-sectional area of the discharge port 47. The regeneration discharge port 54 'may be installed to be fitted to a part of the discharge port 47, but is not necessarily the case, and may be configured to be positioned near the discharge port 47 as shown in the illustrated embodiment.

Hereinafter, the operation of the cold air circulation structure of the refrigerator according to the present invention having the configuration as described above will be described.

First, the cold air circulation is performed inside the refrigerator. When the refrigeration cycle is operated, the compressor (not shown) is driven to move the refrigerant along the inside of the cycle. In addition, a relatively low temperature refrigerant is delivered to the evaporator 39 to generate cold air.

The cold air generated by the evaporator 39 is circulated inside the refrigerator by the blowing fan 44. That is, the cold air is transferred to the space between the shroud 40 and the grill pan 42 by driving the blower fan 44, and a part of the cold air is transferred to the freezing chamber 33 through the outlet of the grill pan 42. do. The remainder is lowered in the space between the shroud 40 and the grill pan 42 and passes through the barrier 34 to be supplied to the refrigerating duct 46.

The cold air delivered to the refrigerating chamber duct 46 is discharged onto each shelf 35 ′ in the refrigerating chamber 35 through each discharge port 47 while descending along the refrigerating chamber duct 46. The cold air discharged as described above circulates inside the refrigerating chamber 35 to cool the stored product.

As described above, the cold air delivered to the freezing compartment 33 and the refrigerating compartment 35 is returned to the evaporator 39 through the freezing compartment return passage 48 and the refrigerating compartment return passage 49, and then heat exchanged again. To circulate.

Meanwhile, the regeneration fan 52 sucks cold air from one side of the refrigerating chamber 35 and discharges it to the other side. The regeneration fan 52 is preferably driven when the blower fan 44 is not operated. . Of course, while the regeneration fan 52 is operated during the operation of the blower fan 44, it is possible to prevent the air of a relatively low temperature from being returned to the evaporator 39.

Once the inside of the refrigerating chamber 35 reaches a set temperature, the operation of the heat exchange cycle is stopped and the blower fan 44 is also stopped. The regeneration fan 52 is preferably operated in such a state.

That is, the lower part of the refrigerating chamber 35 and the vicinity of the vegetable chamber 36 generally have a relatively higher temperature than the set temperature. This is because the lower part of the refrigerating chamber 35 and the vicinity of the vegetable compartment 36 are portions corresponding to the distal end of the refrigerating chamber duct 46.

Therefore, when the regeneration fan 52 is operated, a flow of cold air is generated inside the refrigerating chamber 35 as indicated by arrows in FIG. 3, and the temperature inside the refrigerating chamber 35 is uniformly maintained by the flow of the cold air. It can be maintained.

That is, when the regeneration fan 52 is operated, air in the refrigerating chamber 35 is sucked into the regeneration duct 50 through the regeneration suction port 47 ′. In addition, the sucked air is delivered to the upper portion of the regeneration duct 50 and discharged to the upper portion of the refrigerating chamber 35 through each regeneration discharge port 54.

In particular, the air near the vegetable chamber 36 is sucked into the regeneration duct 50 by the driving of the regeneration fan 52, and the cold air of the upper part of the refrigerating chamber 35 is transferred to the lower side of the refrigerating chamber 35. The temperature can be kept uniform.

Meanwhile, in the present specification, the present invention has been described as an embodiment applied to an upright refrigerator, but it will be appreciated by those skilled in the art that the present invention can be applied to a parallel refrigerator within the scope of the claims.

According to the cold air circulation structure according to the present invention as described in detail above, the temperature inside the refrigerating compartment can be maintained as a whole uniformly, preventing the cool air of a relatively low temperature is transferred to the evaporator to prevent heat exchange, thereby increasing the efficiency of the refrigerator. Will be.

Claims (4)

With heat exchanger to generate cold air, A cold air supply passage for transferring cold air generated in the heat exchanger to a storage space; A cold air return flow path for returning cold air circulated through the storage space to the heat exchanger; And a cold air regeneration means for sucking cold air from one side of the storage space and discharging it to the other side of the storage space. According to claim 1, wherein the cold air regeneration means and the regeneration fan for sucking cold air on one side of the refrigerating chamber, The cold air circulation structure of the refrigerator, characterized in that consisting of a regeneration duct for transferring the cold air sucked by the regeneration fan to the other side of the refrigerating chamber. The cold air circulation structure according to claim 1 or 2, wherein the regeneration duct is provided inside the cold air supply passage, and the discharge port thereof is configured to coincide with the discharge port of the cold air supply passage. The cold air circulation structure according to claim 3, wherein the cold air regeneration fan is located at a lower side of the refrigerating compartment to recycle cold air to the upper portion of the refrigerating compartment.