KR20020015242A - The cool-air supplying structure for refrigerators - Google Patents

Abstract

PURPOSE: Cold air circulation structure of a refrigerator is provided to improve the refrigeration efficiency of a refrigerant by preventing reduction of a heat exchange area between an evaporator and cooling air and the interference on the cooling air and to prevent the waste of electricity by efficiently supplying cooling air. CONSTITUTION: Cold air circulation structure of a refrigerator comprises a refrigerator body(20) having a storage space, a heat exchanger generating cooling air for decreasing the temperature of the storage space, a grill fan(24) forming the rear wall of the storage space and having many cooling air discharge outlets(24a) to discharge the cooling air to the storage space and intake ports(24b) to return the cooling air into the heat exchanger, and a shroud(23) forming a cooling air path and having many supply paths(23a) to discharge the cooling air to the cooling air discharge outlets(23b) and return paths to return the cooling air to the heat exchanger from the cooling air intake ports. Through the many cooling air intake ports and the return paths, the cooling air returns to the heat exchanger through many paths. The reduction of a heat exchange area of the cooling air and the heat exchanger due to concentrated refrigeration of the lower end portion of the heat exchanger is avoided. Therefore, the refrigerant efficiency is improved.

Description

The cool-air supplying structure for refrigerators}

The present invention relates to a refrigerator, and more particularly, to a structure of circulating cold air in a freezer compartment in a parallel refrigerator.

In general, the parallel refrigerator has a main body 1 formed in such a manner that the freezing compartment F and the refrigerating chamber R are arranged side by side with respect to the central insulation wall B as shown in FIG. 1. In the front part of (1), each door 2a, 2b for opening and closing of the freezer compartment F and the refrigerating compartment R is hinged with the said main body 1.

The parallel refrigerator having such an external shape maintains the freshness of the food by circulating the cold air generated by the realization of the freezing cycle in the freezing compartment F and the refrigerating compartment R and lowering the temperature to an appropriate temperature suitable for freezing and refrigeration. And it is configured to be stored for a long time, the freezer compartment (F) and the refrigerating chamber (R) is provided with a plurality of shelves (S), to accommodate food or storage containers.

2 illustrates a structure of a freezer compartment of a conventional parallel refrigerator. As shown in the drawing, an evaporator 3 is installed at the rear side of the freezing chamber F to generate cold air circulating in the refrigerator. The evaporator 3 generates cold air by heat-exchanging the low temperature refrigerant flowing therein and the surrounding air, and is installed long in the vertical direction. And an upper side of the evaporator is provided with a blowing fan (4) for circulating the cold air generated by the evaporator (3).

On the other hand, the shroud 5 is installed in front of the evaporator (3). Referring to FIG. 3A, the shroud 5 has a supply passage 5a through which cold air is discharged by the blowing force of the blowing fan 4, and a freezing chamber F is circulated at the lower end thereof. A return passage 5a is formed in which cold air returns to the evaporator 3 side.

And the grill pan 6 which forms the rear wall of the freezer compartment F is provided in front of the shroud 5. Referring to FIG. 3B, the grill pan 6 has a plurality of cold air discharge ports 6a formed in multiple stages from the upper end to the stop portion, and cold air circulating in the freezing chamber F is disposed at the lower end of the return passage 5a. The cold air suction opening 6b is formed so as to be returned to the evaporator 3 side through).

In addition, a shield 7 is provided between the shroud 5 and the grill pan 6 to divide the space therebetween into a portion to which cold air is supplied and a portion to which cold air returns. That is, the upper space of the shield 7 is a cold air supply path (8) for forming a flow path for the cold air introduced through the supply passage (5a) to the cold air discharge port (6a), the shield ( 7) The lower space is a cold air return path (9) for forming a flow path for cooling air introduced through the cold air inlet (6b) and then returning to the evaporator (3) side through the return passage (5b) after circulating the freezer compartment (F). )

Looking at the cold air circulation process of the freezing compartment (F) configured as described above, as the blower fan (4) is driven to rotate in one direction, the cold air generated in the evaporator (3) is supplied to the cold air through the supply passage (5a) The cold air flows into the path 8, and the cold air descends along the cold air supply path 8, and is discharged into the freezing chamber F through the cold air discharge port 6a formed in the grill pan 6.

In addition, the cold air supplied to the freezing chamber F and circulated becomes relatively high in the heat exchange process with the food being stored. The cold air thus heated to the cold air return path (9) through the cold air inlet (6b) of the grill pan 6, passes through the return passage (5a) of the shroud (5) to the evaporator (3) side It is returned, and this process is repeated to keep the freezer compartment F at a low temperature below a predetermined temperature.

However, the conventional freezer compartment cold air circulation structure configured as described above has the following disadvantages.

In the conventional cold air circulation structure, a path for returning the cold air circulating through the freezer compartment F to the evaporator 3 is formed as one path. That is, the cold air is composed of a single path for returning through the cold air suction port 6b of the grill pan 6 and the return passage 5b of the shroud 5.

On the other hand, in the evaporator 3 generally, moisture contained in the returning cold air condenses on the surface of the low temperature evaporator 3 and freezes to form frost. However, when the cold air returns only to a single path under the evaporator 3 as in the related art, the above-mentioned icing occurs intensively in the lower end of the evaporator 3, causing a thick drop.

However, the accumulated castle acts as a flow resistance that prevents the flow of cold air by blocking the space between the evaporators 3, so that the cold air does not pass through the evaporator 21 and escapes out of the evaporator 21. do. In this case, the contact area between the cold and the evaporator 21 is reduced, and the heat exchange efficiency of the evaporator 3 is lowered, thereby increasing the temperature of the cold air supplied to the freezing chamber F. In addition, since the flow of cold air is interfered by the accumulated frost as described above, there is a problem of reducing the amount of air flow. Therefore, as a result, the temperature of the freezer compartment F rises, the operating efficiency of the refrigerator decreases, and the user has a problem of lowering the confidence in the product performance.

In addition, in order to remove the accumulated frost as described above, the defrost heater 10 is usually installed below the evaporator 3, and the defrost heater 10 is heated to remove the frost. However, when the defrosting process proceeds as described above, since the moisture evaporated by the heat of the defrost heater 10 is discharged only through the supply passage 5a of the shroud 5, the moisture is the grill pan 6 As a result of being concentratedly discharged at the upper end of the c), it is formed on the rear surface of the grill pan 6 and freezes, thereby causing a problem of blocking the cold air discharge port 6a on the grill pan 6.

In this case, since the cold air is not supplied to the upper portion of the freezer compartment (F), the temperature rises, resulting in a problem such as thawing and spoiling of the stored food, which may act as a fatal defect in product performance. Since refrigeration capacity is reduced compared to the power used, there is a problem that unnecessary power consumption is used.

An object of the present invention is to improve the problems of the prior art, to provide a freezer compartment cold air supply structure of the refrigerator with improved operating efficiency of the refrigerator.

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

1 is a front view showing the structure of a general parallel refrigerator.

Figure 2 is a side cross-sectional view showing a cold air circulation structure of a conventional parallel refrigerator freezer.

3a-3b is a front view showing the structure of a conventional shroud and grill pan.

Figure 4 is a side cross-sectional view showing a preferred embodiment of the present invention.

Figures 5a-5b is a front view showing the structure of the shroud and grill pan according to an embodiment of the present invention.

Figure 6 is a side cross-sectional view showing an operating state of the embodiment of the present invention.

※ Explanation of code about main part of drawing ※

20: refrigerator body 21: evaporator

22: blowing fan 23: shroud

23a: supply passage 23b: return passage

24: grill pan 24a: cold air outlet

24b: cold air intake 25: shield

26: cold air supply path 27: cold air return path

28: defrost heater F: freezer

Freezer compartment cold air supply structure according to the present invention for achieving the above object is a refrigerator body formed with a storage space; A heat exchanger for generating cold air for lowering the storage space; A grill having a rear wall of the storage space, a plurality of cold air discharge ports through which cold air generated in the heat exchanger is discharged to the storage space, and a plurality of cold air suction ports through which cold air circulated through the storage space returns to the heat exchanger side; With a fan; A supply passage formed between the heat exchanger and the grill pan to form a flow path of cold air, and allowing the cold air generated in the heat exchanger to be discharged to the cold air discharge port, and a plurality of cold air introduced from the cold air suction port to the heat exchanger side. Two return passages are formed.

According to an embodiment of the present invention, the cold air suction port of the grill pan and the return passage of the shroud are formed so that the cold air returned to the heat exchanger side can be returned to the lower and side surfaces of the heat exchanger.

In addition, between the shroud and the grill pan, the space between the supply passage and the cold air discharge port is provided, and the shielding portion for partitioning the return passage and the cold air intake communication portion is provided, the storage space is a freezer compartment It is characterized by that.

According to the above configuration, since the circulation path of the cold air and the discharge path of the moisture during defrosting are formed in a number, the heat exchange efficiency and the blowing force decrease due to the freezing of the evaporator, and due to the freezing of the moisture discharged during defrosting It is possible to prevent the closing of the cold air discharge port, it is possible to improve the operating efficiency of the refrigerator, there is an advantage that can reduce the power consumption.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 shows a structure of a parallel refrigerator according to the present invention. As shown, a freezer compartment F is formed at one side of the refrigerator body 20. The freezer compartment F is configured to be opened and closed by a door 30 fastened to the front portion of the main body 20, and an evaporator for generating cold air for lowering the inside of the refrigerator at the rear side of the freezer compartment F ( 21) is installed. The evaporator 21 generates cold air by heat-exchanging the low-temperature refrigerant flowing inside and the surrounding air in contact with the surface thereof, and is provided in the vertical direction in a long direction. And an upper side of the evaporator 21, a blowing fan 22 for circulating the cold air generated by the evaporator 21 is provided.

The shroud 23 is installed in front of the evaporator 21. The shroud 23 partitions a space between the evaporator 21 and the grill pan 24 forming the rear wall of the freezer compartment F to form a flow path of cold air, and as shown in FIG. The supply passage 23a through which the cool air is discharged by the blowing fan 22, and a plurality of return passages 23b are formed at both sides and the lower end of the interruption portion below the supply passage 23a. Forming a plurality of the return passage (23b) is, by circulating the freezer compartment (F) and the return of the cold air to the evaporator 21 side through a number of paths, where the freezing is concentrated on the lower end of the evaporator (21) It is to prevent.

In addition, the grill pan 24 described above is installed in front of the shroud 23. As shown in FIG. 5B, a plurality of cold air discharge ports 24a are formed in the grill pan 24 through which the cold air supplied through the supply passage 23a is discharged to the freezing chamber F at the upper end and the middle part of the middle portion of the middle portion of the grill pan 24. A plurality of cold air suction ports 24b are formed at both sides and the lower end of the interruption portion so that the cold air circulated through the freezing chamber F through the return passage of the shroud 23 can be returned to the evaporator 21 side.

In addition, between the shroud 23 and the grill pan 24, the supply passage 23a and the cold air outlet 24a communicate a space between the shroud 23 and the grill pan 24, and the return passage The shielding part 25 which partitions so that 23b and cold air suction opening 24b may communicate is provided. Therefore, the upper space of the shield 25 is a cold air supply path 26 for forming a flow path so that cold air introduced through the supply passage 23a is discharged from the cold air discharge port 24a, and the lower space is a freezing chamber ( The cold air circulated through F) flows into the cold air suction port 24b and becomes a cold air return path 27 returning to the evaporator 21 via the return path 23b.

Looking at the operation of the embodiment of the present invention by the configuration as described above with reference to the drawings.

First, when the blowing fan 22 is driven and rotates in one direction, the cool air generated by the evaporator 21 is supplied to the supply passage 23a of the shroud 23 by the blowing force of the blowing fan 22. After being introduced into the cold air supply path 26 through the cold air supply path 26, it descends along the cold air supply path 26 and is discharged into the freezing chamber F through the cold air discharge port 24a formed in the grill pan 24.

The cold air discharged into the freezing chamber F is circulated and heat exchanges with the stored foods to be in a relatively high temperature state. The high temperature cold air is introduced into the cold air return path 27 through a plurality of cold air suction openings 24b formed in the grill pan 24, and then the evaporator 21 through a plurality of return paths 23b. Return to the side.

At this time, the return passage 23b is conventionally formed only at the lower end of the shroud 23, so that a plurality of the return passages 23b are formed at the lower end and the stop portion, so that some of the returning cold air is lowered to the evaporator 21. , Part is returned to the side of the evaporator 21, so that the freezing phenomenon occurring on the surface of the evaporator 21 is not concentrated on the lower end of the evaporator 21, it occurs uniformly on the surface of the evaporator 21 . Therefore, the phenomenon in which the flow of cold air is not interfered by the accumulated frost does not occur, thereby sufficiently securing the heat exchange area of the evaporator 21, and the blowing force of the cold air may also be maintained. As the above-mentioned circulation of cold air is repeated, the freezing compartment F is maintained at a low temperature below a predetermined temperature.

On the other hand, if the above-mentioned frost phenomenon accumulates, a defrost process for removing such frost is performed. The defrosting process is performed by applying power to the defrost heater 28 installed below the evaporator 21 to generate heat, and melting the frost as described above to evaporate it.

At this time, the moisture evaporated by the heat generated by the defrost heater 28 is discharged only through the supply passage 23a of the shroud 23, the shroud 23 according to the present invention is the evaporator 21 Since a plurality of feedback passages 23b are formed in a portion corresponding to one side of the moisture, moisture is also discharged through the feedback passage 23b, and through the dispersion discharge of the moisture, the grill pan 24 has an upper end portion. A phenomenon in which concentrated ice occurs, and thus, the upper cold air outlet 24a of the grill pan 24 is blocked, thereby preventing the temperature of the upper portion of the freezer compartment F from rising.

As described above, the present invention returns the cold air circulating the freezer compartment in the shroud and the grill pan, and by forming a plurality of paths through which the evaporated moisture is discharged during the defrosting operation, freezing is concentrated on the lower end of the evaporator. The technical gist of the present invention is to prevent the phenomenon of closing the cold air discharge port of the grill pan upper end by freezing.

Within the above technical scope, many other modifications to the present invention will be possible to those skilled in the art.

For example, in the above-described embodiment, the middle part of the shroud 23 and the grill pan 24 forms a path through which cold air is supplied to the freezing compartment F, and the cold air is provided to the evaporator 21 on both sides of the stop part. Although the return path is formed, it is also possible to form it in the opposite form, and since the present invention is intended to form a plurality of return paths of cold air, the form of such a path will not be limited.

In addition, in the present invention, the shield 25 is provided as a separate member, but it is also possible to form the shield 25 integrally on the front of the shroud 23 or the back of the grill pan 24.

As described above, the present invention forms a plurality of return passages of the shroud and a plurality of cold air intakes of the grill pan, so that the cold air returning to the evaporator side after circulating the freezer compartment can be returned through various paths. Therefore, the lower end of the evaporator is concentrated freezing, the heat exchange area of the evaporator and cold air is reduced, it is possible to prevent the phenomenon causing interference in the flow of cold air, there is an advantage that the operating efficiency of the refrigerator can be improved.

In addition, the return environment of the cold air also performs the function of the discharge path of the moisture during the defrosting operation, since the moisture is dispersed and discharged, it is possible to prevent the concentration of ice due to the moisture in one place, and to minimize the growth of freezing Can be. In addition, it is possible to prevent the phenomenon that the cold air discharge port is closed due to freezing, it is possible to prevent the temperature rise inside the freezer, and to supply the cold air as efficiently as the power supplied, it is possible to prevent waste of power consumption.

Claims (4)

A refrigerator body having a storage space; A heat exchanger for generating cold air for lowering the storage space; A grill having a rear wall of the storage space, a plurality of cold air discharge ports through which cold air generated in the heat exchanger is discharged to the storage space, and a plurality of cold air suction ports through which cold air circulated through the storage space returns to the heat exchanger side; With a fan; A supply passage formed between the heat exchanger and the grill pan to form a flow path of cold air, and allowing the cold air generated in the heat exchanger to be discharged to the cold air discharge port, and a plurality of cold air introduced from the cold air suction port to the heat exchanger side. Cold air circulation structure of the refrigerator comprising a shroud formed with two return passages. The cold air circulation structure of the refrigerator of claim 1, wherein the cold air suction port of the grill pan and the return passage of the shroud are formed so that cool air returning to the heat exchanger side can be returned to the bottom and side surfaces of the heat exchanger. . The shield according to claim 1 or 2, wherein the space between the shroud and the grill pan is divided into a portion in which the supply passage and the cold air discharge port communicate with each other, and a portion in which the return passage and the cold air suction port communicate with each other. Cold air circulation structure of the refrigerator, characterized in that the additional provided. The cold air circulation structure according to claim 1, wherein the storage space is a freezer compartment.