KR20070107953A - Refrigerator - Google Patents

Abstract

A refrigerator is provided to facilitate draining of defrosted water of a fan and to prevent inconsistent distribution of temperature within a cooling chamber with a simplified cover structure, thereby achieving equal distribution of temperature on each portion within the cooling chamber. A refrigerator comprises a body unit(100), a cooling chamber(200), a cool air supply chamber(300), a fan(500), and a cover(400). The cooling chamber is defined within the body unit. The cool air supply chamber is provided with a cooler(310) which generates cool air supplied to the cooling chamber. The fan discharges the air generated from the cooler to the cooling chamber. The cover defines the cooling chamber and the cool air supply chamber, having the fan on its one side. The cover includes an incline(420) wherein a fan-mounted portion is inclined forwards by a predetermined angle and a guide(430) is installed on a lower side of the incline to control discharge of cool air and guide draining of defrosted water of the fan, thereby ensuring equal distribution of cool air discharged from the fan over the entire cooling chamber and facilitated draining of defrosted water.

Description

Refrigerator {REFRIGERATOR}

1 is an exploded perspective view showing a configuration inside a cooling chamber of a conventional refrigerator.

Figure 2 is a side cross-sectional view showing the structure of a cooling chamber of the refrigerator according to the present invention.

3 to 5 are front views showing the interior of the cooling chamber of the refrigerator according to the present invention, respectively, illustrating first to third embodiments of the present invention.

Figure 6 is a side cross-sectional view showing the cold air circulation inside the cooling chamber of the refrigerator according to the present invention.

7 is a view showing the temperature distribution inside the cooling chamber of the refrigerator according to the present invention through an isotherm.

* Description of symbols on the main parts of the drawings *

100: main body 200: cooling chamber

300: cold air supply chamber 310: cooler

400: cover 410: cover body

411: communication groove 420: inclined portion

500: fan 430: guide member

431: Rib 432: Slit

The present invention relates to a refrigerator, and more particularly, to a refrigerator having a means for more uniform temperature distribution inside the refrigerator's cooling chamber, reducing loss of cold air, and facilitating the discharge of the defrost water when the fan is defrosted. It is about.

Generally, a refrigerator is a mechanism that cools a cooled object by cold generated from a refrigeration cycle device by a compressor, a condenser, an expansion valve, and an evaporator, and cools a freezer compartment and a cooled object that freezes the cooled object below the freezing point. Cooling chambers, such as a refrigerating chamber, are usually provided.

In general, a refrigerator has a refrigerator compartment at a lower side and a freezer compartment at an upper side. Recently, a so-called Bottom Mounted Freezer (BMF) refrigerator has been introduced in which a freezer compartment is disposed below the refrigerator for the convenience of a user. TECHNICAL FIELD This invention is applicable to all the refrigerators provided with a cooling chamber, but it is related with the structure of the freezer compartment of a BMF refrigerator especially.

The cooling chamber cools (freezes) the object to be stored therein by cold air generated in a cooler such as an evaporator. The structure of the cooling chamber (particularly the freezer compartment) of the conventional refrigerator is as shown in FIG. 1. And a cold air supply chamber 30 including a main body 10 forming a heat sink, a cooling chamber 20 provided in the main body 10, and a cooler 31 for supplying cold air to the cooling chamber 20. .

In addition, there is provided a front cover 60 and a rear cover 61 which partition the cooling chamber 20 and the cold air supply chamber 30 and cover the cooler 31, and a blower fan at an upper end side of the rear cover 61. 50) is installed. The blowing fan 50 sucks cold air generated by the cooler 31 and blows air into the space between the front cover 60 and the rear cover 61.

A cold air flow path is formed between the front cover 60 and the rear cover 61 by a cold guide 63 formed on the rear cover 61, and the blower fan 50 sucks cold air to the front cover. Cold air is supplied to each cold air flow path formed by the cold air guide 63 between the 60 and the rear cover 61.

The cold air flowing along each cold air guide 63 is discharged to the cooling chamber 20 through the discharge ports 62 formed in the front cover 60. The cold air discharged into the cooling chamber 20 as described above is used to cool the object to be cooled and then returns to the cold air supply chamber 30 again.

However, since the cooling chamber of the conventional refrigerator includes both the front cover and the rear cover as shown in FIG. 1, the assembling structure is complicated, and the effective volume of the cooling chamber is narrowed. The amount of cold air discharged from the discharge port formed at the last part of the cold air flow path may be reduced while passing through the cold air flow path between the rear covers, resulting in uneven distribution of the entire temperature distribution of the cooling chamber. There was a problem in that a drainage flow path should be provided separately from the cold air flow path.

In addition, if the cover of the cooling chamber is configured as one cover instead of the front cover and the rear cover as described above, there is a problem that the temperature distribution of the cooling chamber is uneven because the blower fan blows cold air only toward the front of the cooling chamber. .

The present invention is to solve the above problems, an object of the present invention is to simplify the cover structure of the cooling chamber, but to uniformize the temperature distribution in the cooling chamber and to facilitate the discharge of defrost water To provide.

The refrigerator according to the present invention for achieving the above object, the main body, a cooling chamber provided inside the main body, a cold air supply chamber provided with a cooler for generating cold air to be supplied to the cooling chamber, and the cold air generated in the cooler the cooling A fan for discharging to the chamber, and a cover partitioning the cooling chamber and the cold air supply chamber and having the fan installed on one side thereof, wherein the cover includes an inclined portion in which the fan installed portion is inclined forward at a predetermined angle from the fan. It is characterized in that the discharged cold air is evenly transmitted to the cooling chamber.

The cover may further include a guide member provided at a lower side of the inclined portion to control discharge cold air and guide discharge of defrost water from the fan.

The apparatus may further include a communication groove provided at a lower side of the guide member to allow cold air circulating in the cooling chamber to return to the cold air supply chamber.

The guide member may include at least one rib formed in a direction crossing the inclined portion and the communication groove.

In addition, the guide member is characterized in that it comprises a slit to discharge the defrost water of the fan.

In addition, the inclined portion is characterized in that it has an inclination angle of 15 degrees substantially forward from the vertical direction.

Hereinafter, a preferred embodiment of a refrigerator according to the present invention will be described with reference to the drawings.

Figure 2 is a side cross-sectional view showing the structure of a cooling chamber of the refrigerator according to the present invention, Figures 3 to 5 is a front view showing the inside of the cooling chamber of the refrigerator according to the present invention the first to third embodiments of the present invention 6 is a side cross-sectional view showing a cold air circulation inside the cooling chamber of the refrigerator according to the present invention. 7 is a view showing the temperature distribution inside the cooling chamber of the refrigerator according to the present invention through an isotherm.

As shown in FIG. 2, the refrigerator according to the present invention generates a main body 100 forming an exterior, a cooling chamber 200 provided inside the main body 100, and cold air supplied to the cooling chamber 200. And a cold air supply chamber 300 in which a cooler 310 to be installed is installed, and the cooling chamber 200 and the cold air supply chamber 300 are partitioned by a cover 400. Refrigerator doors, refrigeration cycle devices and other equipment are mostly the same configuration as a typical refrigerator.

The cover 400 includes a cover body 410 formed of a flat plate and an inclined portion 420 having an upper portion of the cover body 410 inclined at a predetermined angle. The inclined portion 420 is inclined in a direction looking forward and downward of the cooling chamber 200, that is, inclined to have a predetermined angle from the vertical direction toward the front of the cooling chamber 200.

The inclined portion 420 is provided with a fan 500 for supplying the cold air generated in the cooler 310 to the cooling chamber 200.

Since the fan 500 is installed in the inclined portion 420 of the cover 400, the direction in which the fan 500 supplies cold air to the cooling chamber 200 also depends on the inclination angle of the inclined portion 420.

Rather than discharging cold air only forward, the fan 500 discharges cold air in a diagonal direction forward and downward, that is, simultaneously blows cold air forward and downward of the cooling chamber 200, The temperature distribution can be made more uniform.

As described above, the inclined portion 420 is formed by inclining the upper portion of the cover 400 in which the fan 500 is installed such that the fan 500 faces the front and the bottom of the cooling chamber 200, but the cover 400 is provided. It is not necessary to form all of the upper side of the inclined, it is also possible to form only partially inclined fan 500 is installed.

On the other hand, the cover 400 has a communication groove 411 is formed so that the cold air circulated in the cooling chamber 200 flows into the cold air supply chamber 300 again. The communication groove 411 may be formed anywhere in the cooling chamber 200 and may be formed at a place other than the cover 400, but at the lower end side of the cover body 410 of the cover 400. It is preferable to form.

As described above, the fan 500 is installed at the upper end side of the cover 400 and the communication groove 411 is formed at the lower end side of the cover 400, and the fan 500 moves downward from the cooling chamber 200. Since the cold air is discharged, all the cold air blown by the fan 500 is not transferred to the object to be cooled inside the cooling chamber 200, and a part thereof is directly returned to the cold air supply chamber 300 through the communication groove 411. There is a risk of inhalation.

Therefore, the guide member 430 is provided between the fan 500 and the communication groove 411 or between the inclined portion 420 and the communication groove 411 so that cold air discharged through the fan 500 is in the communication groove 411. ) To control the discharge cold air so as not to be sucked in immediately. That is, the guide member 430 serves as a barrier between the fan 500 and the communication groove 411. The guide member 430 is formed of a rib having a predetermined width. A more detailed description of the guide member 430 will be described with reference to FIGS. 3 to 5.

3 to 5 show the inside of the cooling chamber 200 as viewed from the front, as shown in FIG. 3, the guide member 430 is formed of three ribs 431.

That is, the rib 431 having a predetermined width is formed in a direction crossing the inclined portion 420 (or the fan 500) and the communication groove 411.

The guide member 430 may not only prevent a part of the cold air discharged from the fan 500 from being directly sucked back into the communication groove 411, but also cover the defrosting of the cooler and the fan 500. It also functions to guide the defrost water flowing through the 400 to be easily discharged. Defrost water is configured to be guided by the guide member 430 flows to the place where the defrost water is discharged, guided by the guide member 430 from the fan 500 flows through the cover 400 Defrost water flows into the communication groove 411 and meets the defrost water flowing out of the cooler and is discharged through a discharge port (not shown).

The guide member 430 forms the ribs 431 to be inclined so that the defrost water can easily flow out, and a slit 432 is formed at the end of each rib 430. That is, as shown in FIG. 3, the ribs 431 of the "shape" type are provided in the substantially center portion of the cover body 410, and the ribs 431 of the "/" and "shape" shape are respectively provided at both ends thereof. Is placed with a slight gap to form the slit 432. Therefore, the defrost water flowing down from the fan 500 is split into both sides from the center rib and flows into the ribs on both sides thereof, and passes through the slit 432 to be discharged into the communication groove 411.

4 and 5 show that the guide member 430 may be variously formed, as shown in FIG. 4, the guide member 430 may be formed as one rib 431, and FIG. As shown in FIG. 5, the guide member 430 may also be formed as two ribs 431.

In the case of the guide member 430 illustrated in FIG. 4, since the rib 431 is one, a slit 432 is formed in the center portion of the rib 431 formed in a “∨” shape.

In FIG. 5, the guide member 430 forms a "＼" type rib and a "/" type rib so that each end thereof forms a slit 432.

3 to 5 illustrate some forms of the guide member 430, which are only some examples and more various embodiments are possible. For example, in FIG. 4, the ribs may be formed in a “∧” shape so that defrost water flows into the communication grooves at both ends thereof.

On the other hand, the operation of the refrigerator according to the present invention will be described with reference to FIG.

When cold air is generated in the cooler 310 by a series of refrigeration cycle devices (not shown), the cold air supply chamber 300 in which the cooler 310 is installed and the upper side of the cover 400 partitioning the cooling chamber 200 are installed. The fan 500 sucks this and discharges cold air to the cooling chamber 200.

At this time, since the fan 500 is inclined at a predetermined angle, preferably at an angle of about 15 °, toward the front side of the cooling chamber 200 from the vertical direction, the cold air is in front of the cooling chamber 200. It is discharged downward and thereby transmits cold air evenly to the cooling chamber 200, so that the temperature distribution can be made uniform.

On the other hand, the cold air discharged by the fan 500 through the communication groove 411 formed on the lower side of the portion where the fan 500 is installed, that is, the lower end of the cover body 410 portion of the cooling chamber 200 After circulation, it is sucked back into the cold air supply chamber 300.

In addition, a guide member 430 is formed in the space between the fan 500 and the communication groove 411, so that the fan 500 is inclined, thereby directly re-suctioning the discharge cold air into the communication groove 411. To prevent cold air from flowing toward the inside of the cooling chamber 200, and when defrost is performed by a defrost heater (not shown) provided at one side of the cooler 310 after a predetermined cooling time, the defrost heater (not shown) is used. The frost formed on the fan 500 melts and flows along the cover 400, and the defrost water is guided by the guide member 430 to flow toward the communication groove 411. Defrost water flowing into the communication groove 411 is combined with the defrost water generated in the cooler 310 is discharged through the discharge port (not shown).

On the other hand, Figure 7 shows the temperature distribution inside the cooling chamber of the refrigerator according to the present invention. The temperature distribution inside the cooling chamber of the refrigerator according to the present invention of FIG. 7 shows the temperature distribution with the inclination angle of the inclined portion of the cover about 15 °, and each part of the cooling chamber is between -20 ° C and -19 ° C It can be seen that the temperature distribution is very uniform. Figure 7 shows the results of experimenting with the temperature of the cold air at a very low temperature of-20 ℃. The temperature of the cold air is not necessarily determined, but can be adjusted as much, and it can be seen that the temperature distribution inside the cooling chamber becomes uniform due to the configuration of the cooling chamber employed in the present invention.

In the above experimental example, the inclination angle of the inclined portion of the cover was about 15 °, which was the inclination angle to obtain the best effect, and the most preferable effect was obtained even when the inclination angle was made smaller than 15 ° or somewhat larger than 15 °. Although not possible, some desirable effects can be obtained.

The refrigerator according to the present invention having the above characteristics can simplify the structure of the cover partitioning the cooling chamber and the cold air supply chamber, thereby eliminating the temperature distribution imbalance inside the cooling chamber so that there is almost no temperature difference in each part of the cooling chamber. In addition, there is an effect that can easily discharge the defrost water of the fan.

Claims (6)

A main body, a cold air supply chamber provided with a cooling chamber provided inside the main body, a cooler for generating cold air supplied to the cooling chamber, a fan for discharging cold air generated in the cooler to the cooling chamber, and the cooling chamber and the cold air supply chamber, It includes a cover on which the fan is installed, The cover includes a inclined portion formed by the fan is installed to be inclined at a predetermined angle in the forward portion so that the cold air discharged from the fan is evenly transmitted to the cooling chamber. The method of claim 1, The cover further comprises a guide member which is provided on the lower side of the inclined portion to control the discharge cold air and to guide the defrost water discharge of the fan. The method of claim 2, And a communication groove provided at a lower side of the guide member to allow cold air circulating in the cooling chamber to return to the cold air supply chamber. The method of claim 3, The guide member is a refrigerator, characterized in that it comprises at least one rib formed in the direction crossing the inclined portion and the communication groove. The method according to any one of claims 2 to 4, The guide member is a refrigerator, characterized in that it comprises a slit to discharge the defrost water of the fan. The method of claim 1, And said inclined portion has an inclination angle of substantially 15 degrees forward from the vertical direction.

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