KR0132888Y1 - Cooling apparatus of a refrigerator - Google Patents

Abstract

The present invention relates to a cooling device of a refrigerator, and in particular, an evaporator having a function of generating air flow is installed in the middle of the return duct, and the upper and lower parts are separated from the center of the evaporator to provide a freezing compartment and a refrigerating chamber air circulation path, and a return duct. The front side of the system adopts a simple structural improvement that arranges the freezing compartment air circulation fan and the refrigerating compartment air circulation fan up and down respectively, so that the effective space increase effect of the freezer compartment can be expected, and the effect of minimizing frost phenomenon and According to the present invention, it is possible to maximize the operation efficiency of the evaporator and the overall cooling system, and to prevent the airflow mixing phenomenon according to the independent configuration of each air circulation line, thereby eliminating the fear of odor diffusion or concern about increasing the frost formation rate.

Description

Refrigerator chiller

1 is a configuration diagram showing a typical cooling cycle.

2 is a schematic cross-sectional view showing a refrigerator structure to which a conventional cooling cycle is applied.

3 is a schematic cross-sectional view showing the structure of a refrigerator to which the present invention is applied.

* Explanation of symbols for main parts of the drawings

21: freezer 22: cold storage room

23: return duct 24: evaporator

25: separation plate 26: freezer air inlet hole

27: air circulation path 28: freezer air circulation path

29: refrigerating chamber air inlet hole 30: air outlet

31: refrigerating chamber air circulation path 32, 33: blowing fan

The present invention relates to a cooling device of a refrigerator to obtain a predetermined freezing and refrigerating effect by circulating a refrigerant, and in particular, by installing an evaporator in a horizontal state in a return duct that divides a freezing compartment and a refrigerating compartment, and at the same time, a cold air passage of a freezing compartment and a refrigerating compartment. Are independently formed, and the evaporator is divided into two parts so that the upper side is used for the freezer compartment and the lower side is used for the refrigerating compartment, while each blower fan installed by the airflow forced circulation means is located in the direction of the door side located in front of the evaporator. By installing the return duct at the front part, it prevents the mutual flow of circulation airflow to maximize the operation efficiency of the evaporator and the blower fan and the overall efficiency of the cooling device. It is connected to the refrigerator's cooling system that enables the side position to be moved to obtain the effective space increase effect of the freezer compartment. It is.

A general cooling device applied to a refrigerator is to repeat the circulation of the refrigerant filled in the refrigerant pipe in the process of compression, condensation, expansion, and evaporation, so that the ambient temperature is drastically lowered by the refrigerant gas, and a predetermined freezing and cooling effect is accompanied. .

Such a cooling apparatus includes a compressor 2 for compressing a refrigerant at a high temperature and a high pressure, a condenser 3 for condensing the compressed refrigerant at a low pressure and a high pressure state, and a condensed refrigerant at a low temperature as shown in FIG. It consists of a capillary tube (4) to depressurize and the evaporator (1) for reducing the ambient temperature by heat exchange with hot air in the chamber, each of which is interconnected by a refrigerant pipe (5) filled with refrigerant gas.

As shown in FIG. 2, the refrigerator structure to which the cooling device is applied has a freezing compartment 6 for storing food in a frozen state and a cold jaw chamber 7 for storing food in a refrigerated state. The air duct is connected to the air flow circulation path 10 at the rear side of the freezing compartment 6, the refrigerating compartment 2, and the refrigerator based on the idea of the plate 9 in the return duct 8. While 11 and 12 are respectively provided, an evaporator 1 having a substantial cold air generation function and one or two blower fans 13 for forced air flow are provided on the air flow circulation path 10 at the rear side of the freezing chamber 6. It consists of installed structure.

Looking specifically at the circulation process of the cold air flow realized by such a conventional structure, the cold air flow generated through the evaporator 1 is forced into the blower fan 13 while being introduced into the freezer compartment 6 located in front of it. After the forced circulation to the evaporator 1 side through the air circulation path 11 on the upper side of the plate 9 and the re-cooled state, the recirculation process to be re-introduced into the freezing chamber 6 is repeated, while in the refrigerating chamber 7 In the case, the air is introduced into the cold-jail chamber (7) through a separate cold air inlet duct (14), followed by induction circulation to the evaporator (1) side through the air circulation path (12) below the implantation plate (9), and at the same time, the cooling fan. The circulation process reintroduced by (13) is to be repeated.

In the conventional cold air flow circulation structure, the evaporator 1 for generating cold air flow and the blower fan 13 forming the air flow forced circulation means are occupied in the rear wall side of the freezer compartment, thus occupying a fairly large space. The disadvantage of getting that much less space was exposed.

On the other hand, the temperature in the process of recooling through the evaporator 1 in a state where the airflow of the high temperature and high humidity state through the cold-jail chamber 7 and the airflow of the low temperature and low humidity state via the freezing chamber 6 are mixed with each other. Due to the difference, a large amount of frost has to be caught in the evaporator (1), and such frost occurrence has become a major factor that drastically lowers the cooling efficiency of the evaporator (1). There was a disadvantage in that a defrosting device, such as a heater using a power source, must be installed essentially.

This point was not only the main reason for lowering the operation efficiency of the evaporator (1) and the overall cooling system, but also the shortening of the service life due to the overload of the evaporator. As the food odor contained in the air flow is mixed with the air flow of the freezer compartment, the food odor generated in the refrigerating compartment is also supplied to the freezer compartment, causing inconvenience to users.

The present invention is designed to fundamentally solve the structural problems of the conventional refrigerator, by installing an evaporator having a function of forming a cold air in the middle of the return duct and separating the upper and lower parts from the center of the evaporator, thereby freezing and refrigerating air. In addition to providing a circulation path, it is possible to expect the effect of increasing the effective space of the freezer by adopting a simple structure improvement by arranging the freezing chamber air circulation fan and the refrigerating compartment air circulation fan on the front side of the return duct. The first purpose is to separate the upper part of the evaporator for the freezing air circulation for the freezer compartment, the lower part of the evaporator for the cold air circulation for the refrigerating compartment circulation, and each freezer and refrigerating compartment air circulation is independent by a dedicated blower fan. Minimize the conception of frost on sex And the second purpose of maximizing the operation efficiency of the evaporator and the overall cooling system, and to prevent the mixing of the airflow by the independent composition of each air circulation line. There is a third purpose.

Hereinafter, the configuration of the present invention for achieving the above object and the effect according to it will be described in detail based on the accompanying drawings.

As shown in FIG. 3, the evaporator 24 is horizontally installed inside the return duct 23 partitioning the freezing compartment 21 and the refrigerating compartment 22, and separated from the middle of the evaporator 24 as a starting point. The diaphragm 25 forms an upper portion to form a freezer compartment air circulation passage 28 connecting the air inlet hole 26 of the freezing compartment 21 and the airflow circulation passage 27 on the rear side, and at the same time the lower portion of the refrigerator compartment 22 has air. While forming the refrigerating chamber air circulation path 31 connecting the inlet hole 29 and the air outlet path 30, the air inlet (26, 29) directly below the respective air inlet (26, 29) located in front of the return duct (23) The freezer compartment blower fan 32 and the refrigerating compartment blower fan 33 are respectively provided to form a forced air circulation means.

Reference numeral 34 denotes an air inlet hole of the rear wall of the freezer compartment, and 35 denotes a refrigerator compartment air inlet hole grille.

The present invention having such a configuration is a simple structural improvement to move and install the relatively large volume of the evaporator 24 and the blowing fan (32, 33) to the return duct 23, the upper and lower parts of the evaporator (24) Blower fans 32 and 33 are installed in front of each of the freezer compartment and the refrigerating compartment air circulation passages 28 and 31 formed in the furnace, that is, near the respective freezer compartment air inlet 26 and the refrigerator compartment air inlet 29. When forced to blow the air flow toward the evaporator 24 during operation, the air flow forced by the blowing fan (32, 33) is individually re-cooled while passing through the evaporator 24, the upper side of the evaporator 24 The cold air flow passing through the air circulation path 28 is re-introduced into the freezing chamber 21 through the air flow circulation path 27 to perform a predetermined freezing action, and then to the air inlet hole 26 by the suction force of the blower fan 32 which is operated. As it flows in, the air flow circulation process inductively circulated to the evaporator 24 is repeated. On the other hand, the cold air flow through the air circulation path 31 below the evaporator 24 is re-introduced into the refrigerating chamber 22 through the air outlet path 30 to perform a predetermined refrigeration action of the blower fan 33 is operated The air flow circulation process of inducing circulation to the evaporator 24 side while being introduced into the air inlet hole 29 by the suction force is repeatedly performed.

According to the cooling apparatus of the present invention in which a predetermined freezing and refrigerating action is independently performed by such an air circulation process, the operation of the evaporator 24 is performed by allowing the freezing compartment and the refrigerating compartment circulation air to be circulated independently without being mixed with each other. As the efficiency is greatly increased, the effect of minimizing moisture phenomena can be expected, and the operation efficiency of the overall cooling system can be increased, and the overload caused by excessive operation of the evaporator can be effectively eliminated. By moving the bulky evaporator and the blower fan toward the return return duct, the effective space expansion effect of the freezer compartment can be obtained.

In addition, the airflow circulation lines between the freezer compartment and the refrigerating compartment are independently configured to completely eliminate the risk of dispersal of odors contained in the high temperature and high humidity refrigerating compartment airflow and the associated inconveniences, as well as the circulation airflow and the recooling airflow. It is an advantageous design with various advantages, such as minimizing the actual temperature difference and greatly reducing the frosting rate of frost, thereby increasing the overall cooling efficiency by increasing the operation cycle of the defrosting device.

Claims (2)

Compressor, condenser, capillary and evaporator connected through a refrigerant pipe, the evaporator 24 is installed in the middle of the return duct 23 partitioning the freezing chamber 21 and the refrigerating chamber 22, the air flow forced in front In the refrigerator cooling apparatus provided with a circulating blower fan, a separation plate 25 is installed starting from the center of the evaporator 24, and a freezer compartment air circulation path 28 is disposed above the separation plate 25 and a refrigerating compartment below. An air circulation path (31) is provided, respectively, the refrigerator cooling apparatus, characterized in that the air flow circulation action to the freezing chamber (21) and the refrigerating chamber (22) by the blowing fan is independently realized. The refrigerator cooling apparatus according to claim 1, wherein the blowing fan constituting the forced air circulation means is dualized by a freezing chamber airflow circulation fan (32) and a refrigerating compartment airflow circulation blower fan (33).