KR19990060428A - Freezing prevention structure of the cold air supply part of the refrigerator - Google Patents

Abstract

The present invention relates to a freezing prevention structure of the refrigerator cold air supply unit. The present invention provides a damper unit 20 at the end of the cold air flow passage 21 for supplying cold air to the refrigerating chamber 3, and the cold air duct unit 30 for distributing the cold air transferred through the damper unit 20. The cold air discharge ports 31, 32, and 33 were drilled from the lower end of the damper unit 20. In addition, a back flow prevention jaw 40 for guiding the cold air flowing back to the lower portion of the cold air duct portion 30 is formed inside the cold air discharge port 31. In addition, the damper part 20 has a slight gap when the cold air supply from the cold air flow passage 21 is interrupted so that a predetermined amount of cold air can be delivered to the cold air duct part 30. According to such a configuration, since high temperature and high humidity cold air is blocked from being transmitted to the damper part 20 for supplying cold air to the refrigerating compartment, it is possible to block occurrence of freezing in this part.

Description

Freezing prevention structure of the refrigerator cold air supply unit

The present invention relates to a refrigerator, and more particularly, to a freezing preventing air supply structure of the refrigerator cold air supply unit that prevents the high temperature and high temperature cold air in the refrigerating compartment from flowing back to the cold air supply unit supplying cold air to the refrigerating compartment.

1 shows the configuration of a conventional refrigerator according to the prior art and the flow of cold air therein. According to this, the cold air of the predetermined temperature produced by the evaporator 4 is transmitted to the freezing chamber 2 and the refrigerating chamber 3 by the blowing fan 4 '.

Here, it will be described that the cold air is delivered to the refrigerating chamber (3). The cold air delivered by the blowing fan 4 is transmitted to the damper part 5 via the barrier part. The damper unit 5 controls the supply of cold air to the refrigerating chamber 3 according to the refrigerating chamber temperature detected by the refrigerating chamber temperature (not shown).

The damper part 5 is shown in detail in FIG. 2, whereby cold air is transferred from the evaporator 4 in the direction of arrow A, and a baffle 6 is installed laterally with respect to the flow direction of the cold air. It is. The baffle 6 is opened and closed according to the temperature inside the refrigerating compartment 3 sensed by the refrigerating compartment temperature sensor. That is, when the temperature in the refrigerating chamber 3 is higher than a predetermined temperature range suitable for refrigerating, the baffle 6 supplies the low temperature cold air to the refrigerating chamber 3. When the temperature in the refrigerating compartment 3 is within a temperature range suitable for refrigeration, the baffle 6 blocks the supply of cold air.

In addition, a plurality of cold air discharge ports 10a, 10b, and 10c are sequentially formed in the refrigerating chamber discharge duct portion 7 for discharging the low temperature cold air delivered by the opening of the baffle 6 to the refrigerating chamber 3. It is. The cold air discharge port 10a at the upper end of the double discharge duct portion 7 is formed at a position facing the baffle 6.

On the other hand, in the ceiling of the refrigerating chamber 3, a cold air return passage 9, which is a passage through which cold air circulated inside the refrigerating chamber 3 is returned to the evaporator 4, is formed.

In the conventional refrigerating compartment cold air supply structure having such a configuration, when the baffle 6 of the damper portion 5 is opened, cold air delivered from the evaporator 4 is transferred to the discharge duct portion 7, The air is discharged into the refrigerating chamber 3 through the cold air discharge ports 10a, 10b, and 10c which are sequentially formed while descending along the discharge duct 7.

As described above, while the cold air is transferred into the refrigerating chamber 3 through the damper part 5, the damper part 5 and the discharge duct part 7 are cooled by low temperature cold air, and the cold air return flow path 9 is Since the cold air which circulates in the refrigerating chamber 3 and became relatively high temperature (0 degreeC or more) flows, it becomes the temperature which was set relatively.

As described above, when the cool air is supplied to the refrigerating chamber 3 by the damper part 5, the supply of the cold air is cut off when the temperature in the refrigerating chamber 3 reaches a predetermined refrigerating temperature. When the refrigerating compartment temperature sensor detects that the temperature in the refrigerating compartment 3 exceeds a predetermined refrigerating temperature range, the refrigerating compartment temperature supply starts again.

However, in the conventional cold air supply structure as described above, there are the following problems.

That is, when the baffle 6 of the damper part 5 is opened to supply cold air and the supply of cold air is stopped, the relatively high temperature in the refrigerating chamber 3 is discharged from the top cold air outlet 10a of the discharge duct part 7. Cold air flows back and flows into the baffle 6, as indicated by the dashed arrows in FIG.

At this time, the refrigerated cold air is relatively high temperature and humidity because the temperature rises while circulating in the refrigerating compartment 3 and absorbs moisture in the storage inside the refrigerating compartment 3. In addition, as described above, the damper portion 5 is a portion where low temperature cold air continues to flow, and in particular, the baffle 6 is cooled to a relatively low temperature.

Accordingly, as the countercurrent hot and humid cold air contacts the baffle 6, a phenomenon in which the moisture contained in the countercurrent cold air freezes due to the low temperature of the baffle 6 occurs. As described above, if freezing occurs continuously around the baffle 6, a situation may occur in which a flow path for supplying cold air is blocked and thus no supply of cold air occurs.

The reason why a large amount of freezing occurs around the baffle 6 is that the relatively high temperature cold air is collected by moving to the upper part of the refrigerating chamber 3 by convection, and the cold air supplied through the baffle 6. This is because when the abrupt blockage occurs, the space between the cold air discharge port 10a and the baffle 6 becomes momentarily low pressure.

In addition, when cold air is not discharged through the discharge duct part 7, cold air inside the refrigerating chamber 3 is not returned through the cold air return flow path 9. Thus, as shown by the dotted arrow in Fig. 5 from the evaporator 4, as the cold air of the relatively low temperature flows back, freezing occurs in the cold air return passage 9 as well.

Therefore, an object of the present invention is to solve the problems of the prior art as described above to prevent the freezing phenomenon caused by the reflux of the cold air inside the refrigerating compartment to the portion where the cold air is supplied to the refrigerating compartment.

1 is a side cross-sectional view showing the configuration of a typical refrigerator and cold air circulated therein.

FIG. 2 is a detailed view of portion A of FIG. 1; FIG.

3 is a detailed view of portion B of FIG. 1;

Figure 4 is a cross-sectional view showing the main portion of the structure of the refrigerator freezing air supply preventing portion according to the present invention.

Figure 5 is a schematic view showing the configuration of the freezing prevention structure of the refrigerator cold air supply unit according to the present invention.

Figure 6 is a cold air flow diagram showing that the cold air flow is formed by the structure of the refrigerator cold air supply freezer according to the present invention.

* Explanation of symbols for main parts of the drawings

1: refrigerator 2: freezer

3: refrigerating chamber 4: evaporator

4 ': blower fan 5, 20: damper section

6, 23: baffle 7, 30: cold air duct portion

10a, 10b, 10c: cold air outlet 21: cold air flow path

22: cold air gate 25: gap projection

31, 32, 33: cold air outlet

According to a first aspect for achieving the object of the present invention as described above, the present invention provides a cold air supply passage for supplying cold air, cold air control means for controlling the flow of cold air is installed across the cold air supply passage, And a cold air distribution unit for distributing the cold air that has passed through the cold air control means into the refrigerator.

The uppermost cold air discharge port of the cold air distribution unit is provided at a lower end of the cold air control unit, and a reverse flow prevention unit is further provided inside the cold air discharge port to guide the flow of cold air back to the cold air distribution unit.

In the first aspect, even when the cold air control means blocks the cold air supply passage, a predetermined amount of cold air is naturally convection from the cold air supply passage to the cold air distribution unit.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the refrigerator freezing air supply unit freezing structure according to the present invention having the configuration as described above will be described in detail.

Figure 4 is a cross-sectional view showing the main portion of the structure of the refrigerator cold air supply freezing prevention unit according to the present invention, Figure 5 is a schematic view showing the structure of the refrigerator cold air supply unit freezing prevention structure according to the present invention, Figure 6 is The cold air flow diagram shows that the cold air flow is formed by the freezing prevention structure of the refrigerator cold air supply unit.

As shown in FIG. 4, cold air formed in the evaporator 4 is transferred to the refrigerating chamber 3 side through the cold air flow passage 21. The cold air flow passage 21 is formed vertically downward from the evaporator 4 at the rear of the freezing chamber 2 above the refrigerator 1 toward the refrigerating chamber 3 below the refrigerator 1. In addition, a damper part 20 for controlling the flow of cold air through the cold air flow passage 21 is installed at the end of the cold air flow passage 21.

That is, the cold air gate 22 is installed at the end of the cold air passage 21, and the baffle 23 for opening and closing the cold air gate 22 is provided. The baffle 23 is installed horizontally with respect to the ground to open and close across the cold air flow passage 21 formed in the vertical downward. Since the configuration for driving the baffle 23 is a general one, the description thereof is omitted here.

On the other hand, one side of the cold air gate 22, that is, a portion where the tip portion of the baffle 23 is in contact with the cold air gate 22, the gap between the cold air gate 22 and the baffle 23 is not in close contact with each other. The protrusion 25 is formed. The gap protrusion 25 forms a gap between the cold air gate 22 and the baffle 23 when the baffle 23 closes the cold air gate 22. By such a gap, a predetermined amount of cool air is transferred from the cold air passage 21 to the cold air duct portion 30 to be described below.

In addition, a cold air duct unit 30 for evenly distributing cold air having passed through the damper unit 20 into the refrigerating chamber 3 is installed at the inner rear side of the refrigerating chamber. The cold air duct portion 30 is formed with a plurality of cold air discharge ports (31, 32, 33). The cold air discharge ports 31, 32, and 33 are formed in turn at a predetermined interval from the upper end to the lower end of the cold air duct 30, respectively, to evenly supply cold air to the inside of the refrigerating chamber 3. Here, the cold air discharge port 31 formed at the uppermost end of the cold air duct portion 30 is formed at a lower end than the baffle 23 of the damper portion 20.

On the other hand, inside the uppermost cold air discharge port 31 of the cold air duct portion 30, as shown in Figure 5, the backflow prevention jaw 40 is formed. The backflow prevention jaw 40 has relatively high temperature and humidity cold air at the top of the refrigerating chamber 3 at the moment when the baffle 23 shields the cold air gate 22 so that cold air is not transmitted through the cold air flow passage 21. Even if flowed back into the cold air duct unit 30 through the discharge port 31 serves to guide the flow to the lower side of the cold air duct unit 30 is not delivered to the baffle (23).

Hereinafter, the operation of the cold air supply freezing prevention structure according to the present invention with reference to FIG.

Until the temperature in the refrigerating chamber 3 is within a temperature range suitable for refrigeration, the cold air duct unit 30 is formed in the evaporator 4 by opening the baffle 23 and transferred to the cold air passage 21. ). The cold air supplied to the cold air duct part 30 is evenly transmitted to each part of the refrigerating chamber 3 through the cold air discharge ports 31, 32, and 33.

When the cold air is supplied in this way and the temperature in the refrigerating chamber 3 is within a temperature range suitable for refrigeration, the cold air gate 22 is closed by the baffle 23 to block the cold air supply.

At this time, the relatively hot and humid cold air delivered to the upper end of the refrigerating chamber (3) flows as follows. That is, the cold air at the upper end of the refrigerating chamber 3 is flowed back through the uppermost cold air discharging port 31 by the baffle 23 closing the cold air gate 22 and then transferred into the cold air duct unit 30. .

However, as illustrated in FIG. 5, the cold air flowed back into the cold air duct part 30 is guided downward by the backflow prevention jaw 40. In addition, the cold air naturally convection is transferred in the direction of arrow A of FIG. 5 through the gap formed by the gap protrusion 25 between the baffle 23 and the cold air gate 22.

Accordingly, the relatively high temperature and humidity cold flowed backward through the cold air discharge port 31 and guided downward by the backflow prevention jaw 40 to the cold air naturally convexed through the gap. Together with the cold air duct 30 is delivered to the bottom.

In this case, the relatively hot and humid cold air flowed back into the cold air duct part 30 through the cold air discharge port 31 at the moment when the supply of the cold air through the damper part 20 is stopped, becomes relatively low temperature. Since it does not flow toward the baffle 31, no freezing occurs in these portions.

The freezing prevention structure of the refrigerator cold air supply unit according to the present invention as described in detail above flows into the damper unit even when relatively hot and humid cold air in the upper part of the refrigerator compartment flows back to the cold air duct unit at the moment when supply of the cold air to the cold compartment is stopped by the damper unit. Since it is made to flow to the lower portion of the cold air duct, it is possible to expect the effect that freezing does not occur in the refrigerating chamber cold air supply.

Claims (4)

A cold air supply passage through which cold air is supplied, Cold air control means installed across the cold air supply passage to control the cold air flow; And a cold air distribution unit configured to distribute cold air passing through the cold air control means into the refrigerator. The freezing prevention structure of the refrigerator cold air supply unit according to claim 1, further comprising a backflow prevention unit configured to guide the flow of the countercurrent cold air downward in the cold air outlet of the cold air distribution unit. The method of claim 1 or 2, wherein even when the cold air control means blocks the cold air supply passage, the cold air gate and the baffle do not come into close contact with each other so that a predetermined amount of cold air naturally flows from the cold air supply passage to the cold air distribution unit. The freezing prevention structure of the refrigerator cold air supply unit, characterized in that the gap projection is formed. The freezing prevention structure of the refrigerator cold air supply unit according to claim 1 or 2, wherein the uppermost cold air discharge port of the cold air distribution unit is provided at a lower end of the cold air control unit.