KR100794828B1 - Air pressure unit of Refrigerator - Google Patents

Abstract

The present invention relates to a cold air pressurization device capable of efficiently distributing cold air by supplying pressurized cold air to the multi-duct side. The cold air pressurization device according to the present invention communicates with the blower chamber 10 at one end thereof, 22) a damper cylinder 30 having a cold air supply port 30a for supplying cold air to the cold air and a cold air discharge port 30b for discharging cold air to the refrigerating chamber, and suctions cool air from the blower chamber 10 into the damper cylinder 30. Then, the piston 32 for pressurizing the multi-duct 22 through the cold air supply port 30a, the actuator 34 for the operation of the piston 32, the blowing chamber 10 and the damper cylinder 30 ) Between the check valve 301 and the cold air supply port 30a and the cold air discharge port 30b of the damper cylinder 30 when cold air is sucked, and is pressurized. At the time, the opening and closing lead 302 which opens the cold air supply port 30a and the cold air discharge port 30b. , And a temperature sensor for measuring the temperature of the refrigerating compartment, each storage space, achieved by changes in temperature in the refrigerator compartment identified by the said temperature sensor comprises a microcomputer for controlling the operating actuator (34).

According to the cold air pressurization apparatus according to the present invention as described above, the concentrated cooling mode for pressurizing and supplying the cold air introduced into the damper cylinder to the multi duct through the cold air supply port through the cold air supply port.

Therefore, the amount of cold air discharged from the multi duct is increased, and as a result, the temperature distribution of the refrigerating compartment becomes uniform, and thus, it is helpful to improve the commercial property of the refrigerator.

Description

Air pressure unit of refrigerator

1 is a partial cutaway perspective view illustrating a structure of a general side by side type refrigerator.

Figure 2 is a schematic cross-sectional view showing a cold air circulation state in the side-by-side type refrigerator refrigerator compartment by the conventional discharging air circulation system.

3 is a schematic perspective view showing a refrigerator structure to which a cold air pressure device according to an embodiment of the present invention is applied.

Figure 4 is a schematic diagram showing a general cooling mode state of the cold air pressure device according to an embodiment of the present invention.

5 a and b is a schematic diagram showing the concentrated cooling mode operating state of the cold air pressure device according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

       10: blower room 20: damper

       22: multi-duct 30: damper cylinder

       30a: cold air supply port 30b: cold air discharge port

       301: check valve 302: opening and closing lead

       32: piston 34: actuator

The present invention relates to a refrigerator, and more particularly, to a cold air pressurization device capable of efficiently distributing cold air by pressurizing and supplying cold air to a multi-duct side.

The refrigerator is used to freeze or refrigerate food, etc., a case forming a storage space separated into a freezer compartment and a refrigerator compartment, and a freezer compartment door mounted at one side of the case to open and close the freezer compartment and the refrigerator compartment; It is configured to include equipment for forming cold air by forming a refrigeration cycle, such as a compressor, a condenser and an evaporator.

In such a refrigerator, the low-temperature low-pressure gaseous refrigerant is compressed to high-temperature and high-pressure, and the compressed high-temperature high-pressure gaseous refrigerant is cooled and condensed as it passes through the condenser to be converted into a high-pressure liquid phase. As it passes through (not shown), its temperature and pressure are lowered, and then the evaporator continues to change into a low-temperature, low-pressure gas state, taking heat away from the surroundings to cool the air around it. The air cooled through the evaporator is circulated in the freezing and refrigerating chamber by the operation of a blower fan located at one side of the evaporator, thereby lowering the temperature of the freezing compartment and the refrigerating compartment.

On the other hand, the refrigerator is provided with a cold air distribution system for evenly sending the cold air formed around the evaporator to each part of the freezer refrigerator compartment, the cold air distribution system is configured in various forms according to the type of the refrigerator.

Among them, a cold air distribution system applied to a side by side type refrigerator in which a freezer compartment and a refrigerating compartment are horizontally arranged horizontally from side to side, as shown in FIG. It includes a damper 20 is provided to communicate with the blower chamber 10 and the multi-duct 22 connected to the damper 20.

Here, the blowing chamber 10 is located at the top of the evaporator chamber behind the freezing chamber, the damper 20 has a cold air outlet 20a is formed on one side, the bottom surface is made of a structure connected to the multi duct 22, , The multi duct 22 has a structure in which a plurality of cold air outlets 22a are formed at predetermined intervals.

The cold air discharge port 22a of the multi duct 22 is configured to be disposed in each storage space divided based on the storage shelf 16.

According to such a cold air distribution system, the cold air formed around the evaporator and transferred to the blower chamber 10 is distributed to the freezer compartment and the damper 20 by the blower fan 12 provided in the blower chamber 10 and discharged to the freezer compartment. The cold air circulates inside the freezer compartment, and then is directed to the evaporator chamber through the cold air inlet 20b of the bottom of the freezer compartment, and the cold air introduced into the damper 20 is discharged into the cold compartment through the cold air outlet 22a of the side and at the same time, the multi-duct Flows into (22).

As shown in FIG. 2, the cold air discharged to the upper portion of the refrigerating chamber through the cold air discharge port 20a of the damper 20 moves downward through the gap between the door 14 and the storage shelf 16. After the distribution flows into the storage space between the (16), and finally flowed into the cold air inlet (20a) connected to the evaporator chamber, the cold air introduced into the multi-duct 22 through the respective cold air discharge port (22a) Disperse discharge into

That is, according to such a cold air distribution system, since the cold air is dispersed and discharged to the lower and lower portions of the refrigerating chamber by the multi duct 22, the temperature deviation in the refrigerating chamber is not deepened.

However, according to the prior art as described above, because of the flow resistance due to the complicated structure of the multi duct 22, cold air is not smoothly transferred to the multi duct 22 side, and consequently the cooling action is effectively performed in the lower and lower parts of the refrigerating chamber. There is a problem that the commerciality of the refrigerator is lowered, such as the temperature distribution of the refrigerating chamber is uneven because it is not performed.

The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a cold air pressurization device capable of efficiently distributing cold air by pressurizing cold air to a multi-duct side.

In order to achieve the above object, a cold air pressurization apparatus of a refrigerator according to the present invention communicates with one side of a blower chamber, and a damper cylinder having a cold air supply port for supplying cold air to a multi duct and a cold air discharge port for discharging cold air to a refrigerating chamber. And a piston for sucking cold air from the blower into the damper cylinder and then pressurizing the product into a multi duct through a cold air supply port, an actuator for operating the piston, and a blower between the blower and the damper cylinder. Check valve to be transported, the cold air inlet and the cold air outlet of the damper cylinder when cold air intake, the pressurized opening and closing lead to open the cold air supply and cold air outlet when pressurized, and a temperature sensor to measure the temperature of each storage space And, operating the actuator according to the temperature change in the refrigerating chamber, which is detected by the temperature sensor. It comprises a microcomputer that.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 3 to 5, and the same reference numerals will be given to the same parts as in the prior art.

As shown in FIG. 3, the cold air pressurization apparatus of the refrigerator according to the embodiment of the present invention communicates with the blower chamber 10 and one end thereof, and has a cold air supply port 30a and a cold compartment for supplying cold air to the multi duct 22 on the side. The damper cylinder 30 having the cold air discharge port 30b for discharging cold air and the cold air of the blower chamber 10 are sucked into the damper cylinder 30, and then the multi duct 22 is provided through the cold air supply port 30a. Is provided between the piston 32 to pressurize with the pressure, the actuator 34 for operating the piston 32, the blower chamber 10 and the damper cylinder 30, and transfers cool air only to the damper cylinder 30 side. It includes a check valve 301 and the opening and closing lead 302 for opening and closing the cold air supply port (30a) and the cold air discharge port (30b) in accordance with the operation of the piston (32).

Here, the opening and closing lead 302 blocks the cold air supply port 30a and the cold air discharge port 30b when cold air is sucked into the damper cylinder 30, and the cold air supply port 30a when pressurized by the piston 32. ), And the so-called one-way free rotation type to open the cold air discharge port 30b.

In addition, the cold air discharge port (30b) is formed between the cold air supply port (30a) and the piston 32, the cold air supply port (30a) to the back of the damper cylinder 30 to communicate with the multi-duct (22). Is placed.

The cold air distribution operation by the cold air pressurization device according to the present embodiment as described above is divided into a so-called general cooling mode in which the damper cylinder 30 simply serves as a damper, and a centralized cooling mode by pressurizing the piston 32. Each mode is described as follows.

In the general cooling mode, as shown in FIG. 4, the piston 32 is positioned outside the cold air supply port 30a and the cold air discharge port 30b, whereby cold air introduced into the damper cylinder 30 from the blower chamber 10 is provided. It is supplied to the multi duct 22 through the cold air supply port 30a and the cold air discharge port 30b, and discharged to the upper part of the refrigerating chamber.

Therefore, in the general cooling mode, the temperature of the refrigerating chamber is higher because the amount of cold air discharged to the upper portion of the refrigerating chamber through the cold air discharge port 30b is higher than that of the cold air supplied to the lower portion of the refrigerating chamber by the flow resistance of the multi duct 22 as in the related art. The distribution remains uneven.

In the centralized cooling mode, when the temperature of the part (mainly the lower part of the refrigerating chamber) that is cooled due to the cold air discharged from the multi duct 22 increases as the general cooling mode continues for a predetermined time, the temperature distribution of the uneven refrigerating chamber is uneven. In order to correct the problem, first, when the cooling load of a specific storage space of the refrigerating compartment becomes large due to storing foods having a high temperature, the microcomputer detects such a situation and operates the actuator 34 through a temperature sensor.                     

The operation of the actuator 34 causes the piston 32 to move backwards, so that a large amount of cold air flows into the damper cylinder 30 from the blower chamber 10 (see FIG. 5A).

At this time, the opening and closing of the cold air supply port 30a and the cold air discharge port 30b by the operation of each of the opening and closing leads 302 does not cause a phenomenon in which cold air in the upper portion of the multi duct 22 and the refrigerating chamber is introduced into the damper cylinder 30. Will not.

Subsequently, the piston 32 moves by the actuator 34 to a position between the cold air supply port 30a and the cold air discharge port 30b to pressurize the cold air in the damper cylinder 30, wherein the opening and closing lead 302 is automatically By opening, cold air is pressurized and discharged through the cold air supply port 30a and the cold air discharge port 30b.

The cold air pressurized by the piston 32 is strongly discharged to the multi duct 22 and the upper part of the refrigerating chamber. The pressurizing action of the piston 32 causes the piston 32 to pass through the cold air discharge port 30b and to supply the cold air supply port 30a. By continuing until it reaches, consequently, the cold air discharge through the multi-duct 22 is larger than the cold air discharge through the cold air discharge port 30b.

Therefore, according to the concentrated cooling mode, as shown in FIG. 5, the temperature of the lower part of the refrigerating chamber which is intensively supplied by the multi duct 22 is rapidly lowered, and as a result, the temperature distribution of the refrigerating chamber is gradually uniformed. 32) If the operation is continued and the temperature distribution of the refrigerating chamber is uniform, the piston 32 stops at the position outside the cold air discharge port 30b, and thus the normal cooling mode is performed again.

According to the cold air pressurization apparatus of the refrigerator according to the present invention, the cold air is pressurized and supplied to the multi-duct side with a high flow resistance, thereby increasing the amount of cold air discharged from the multi-duct, resulting in a uniform temperature distribution in the refrigerating chamber, and thus improving the commercial property of the refrigerator. This has the advantage of being.

Claims (1)

A damper cylinder having one side end in communication with the blower chamber, and having a cold air supply port for supplying cold air to the multi duct on the side, and a cold air discharge port for discharging cold air to the refrigerating chamber; A piston for sucking cold air from the blower into the damper cylinder and then forcing the multi-duct through the cold air supply port; An actuator for operating the piston, A check valve provided between the blower chamber and the damper cylinder so that cool air is transferred only to the damper cylinder; An opening and closing lead that blocks the cold air supply port and the cold air discharge port of the damper cylinder when inhaling the cold air, and opens the cold air supply port and the cold air discharge port when pressurized; A temperature sensor for measuring the temperature of each storage space in the refrigerator compartment, Microcomputer operating and controlling the actuator according to the temperature change in the refrigerating chamber identified by the temperature sensor Cold air pressurization apparatus of a refrigerator comprising a.

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