KR20020041251A - Direct cooling type refrigerator - Google Patents

Abstract

PURPOSE: A direct cooling type refrigerator is provided to prevent mutual influence of temperature between a left side and a right side evaporator pipes and a left side and a right side accumulators. CONSTITUTION: A refrigerator includes a first storage compartment(52) and a second storage compartment(102); a heat exchange cycle; and a first accumulator(59) and a second accumulator(109). The first storage compartment and the second storage compartment store stores and are formed to be separated from each other. The heat exchange cycle has refrigerant flowing therein and includes a first evaporator pipe(56) and a second evaporator pipe(106) winding around peripheries of the first storage compartment and the second storage compartment. The first accumulator and the second accumulator are installed not to contact either of the first evaporator pipe and the second evaporator pipe to prevent mutual influence of temperature between the first and the second accumulators and the first and the second evaporator pipes.

Description

Direct cooling type refrigerator

The present invention relates to a refrigerator, wherein the accumulator is installed so as not to be adjacent to any one side of the first and second evaporator pipes wound around the outer circumferential surfaces of the first and second storage compartments, thereby eliminating the influence of temperature between the accumulator and the first and second storage compartments. It relates to a direct-cooling refrigerator that can.

A feature of the heat exchanger in the direct chiller is that the heat is maintained at a low temperature by performing heat exchange by heat conduction between the refrigerant flowing in the evaporator pipe and the inside of the evaporator pipe without a blowing fan for blowing cold air. In addition, since the direct-cooling refrigerators are generally provided with storage compartments on the left and right sides, the evaporator pipe is separately installed. Therefore, the installation position of the accumulator connected to the evaporator pipe becomes a problem.

Hereinafter, the structure of a conventional direct-cooling refrigerator will be described in detail with reference to the drawings.

1 is a rear view showing the structure of a conventional direct cooling refrigerator. As shown, the direct chiller consists of two storage compartments. That is, the first storage chamber 12 is shown on the right side of the drawing, and the second storage chamber 2 is shown on the left side.

The second storage compartment 2 serves as a freezing compartment and a refrigerating compartment, and the first storage compartment 12 is used only as a refrigerating compartment. Therefore, the direct chiller can be used for various purposes as well as for storing kimchi.

On the other hand, the first and second storage compartments (2, 12) are respectively surrounded by a storage case is divided into upper and lower ends, respectively. That is, the first storage chamber 12 is divided into a first upper end 12a and a first lower end 12b storage chamber, and the second storage chamber 2 is divided into a second upper end 2a and a second lower end 2b storage chamber, respectively. The storage case is generally made of aluminum. Hereinafter, the storage case of the first storage compartment 12 is called a first storage case 14, and the storage case of the second storage compartment 2 is called a second storage case 4.

Evaporator pipes are wound around upper outer circumferential surfaces of the first and second storage cases 4 and 14, respectively, and heater wires are wound around lower outer circumferential surfaces, respectively. Hereinafter, the evaporator pipe wound around the first storage case 14 is referred to as a first evaporator pipe 16 and the evaporator pipe wound around the second storage case 4 is referred to as a second evaporator pipe 6.

Inside the first and second evaporator pipes 6 and 16, a refrigerant having a low temperature and low pressure flows through an expansion valve (not shown), and the refrigerant in the first and second storage chambers 2 and 12 is cooled by the low temperature refrigerant. The temperature is kept low. The heater wires 7 and 17 serve to mature kimchi in the storage compartment.

In addition, one end of the first and second evaporator pipes 6 and 16 is connected to the accumulator, respectively. That is, two accumulators are connected to the first and second evaporator pipes 6 and 16, respectively. Hereinafter, an accumulator connected to the first evaporator pipe 16 is called a first accumulator 19 and an accumulator connected to the second evaporator pipe 6 is called a second accumulator 9.

The first and second accumulators 9 and 19 separate relatively high temperature refrigerant passing through the first and second evaporator pipes 6 and 16 into a liquid refrigerant and a gaseous refrigerant, and only the gaseous refrigerant is compressor 30. It serves to flow into. In addition, upper pipes 9a and 19a for guiding the gaseous refrigerant to the compressor 30 are provided above the first and second accumulators 9 and 19.

In addition, as shown in the figure, the first and second accumulators 9 and 19 are located at the upper center of the first and second storage cases 4 and 14. That is, it is located in the center of the first upper end 12a and the second upper end 2a. The first accumulator 19 and the second accumulator 9 are alternately provided. In other words, the first and second accumulators 9 and 19 are somewhat overlapped and installed side by side from the side of the direct-cooling refrigerator. This is illustrated well in FIG. 2, which is a cross-sectional view taken along line AA ′ of FIG. 1.

Hereinafter, the operation of the conventional direct-cooling refrigerator will be described in detail with reference to the drawings.

First, the flow of the refrigerant in the direct-cooling refrigerator composed of one compressor 30 and two evaporator pipes 6 and 16 is as follows. That is, the refrigerant compressed by the compressor 30 is directed toward the expansion valve (not shown) through the condenser (not shown). In the expansion valve (not shown), the refrigerant becomes a low temperature low pressure refrigerant and is directed to the evaporator pipes 6 and 16. At this time, the path of the refrigerant is selectively determined according to the temperature change in the furnace.

That is, when the temperature of the first storage chamber 12 becomes lower than the preset temperature, the refrigerant does not flow in the first evaporator pipe 16, and when the temperature of the second storage chamber 2 becomes lower than the preset temperature. The refrigerant does not flow to the second evaporator pipe 6.

The low temperature refrigerant in the first and second evaporator pipes 6 and 16 exchanges heat with air in the storage chambers 2 and 12. In detail, the refrigerant flowing in the first and second evaporator pipes 6 and 16 may be the first and second in the first and second storage chambers 2 and 12 in contact with the first and second evaporator pipes 6 and 16. The heat exchange by heat conduction is performed with the storage cases 4 and 14, respectively, so that the temperature in the said storage chambers 2 and 12 maintains low temperature.

Meanwhile, the refrigerant passing through the first and second evaporator pipes 6 and 16 is directed to the first and second accumulators 9 and 19, respectively. In addition, the first and second accumulators 9 and 19 are separated into gas refrigerant and liquid refrigerant, and only the gas refrigerant flows toward the compressor 30.

As a result, in the conventional direct-cooling refrigerator, the refrigerant flows inside the first and second evaporator pipes 6 and 16 to conduct heat transfer with the first and second storage cases 4 and 14 by conduction. The temperature in the first and second storage chambers 2 and 12 is kept at a low temperature.

Then, the refrigerant selectively flows through the first and second evaporator pipes 6 and 16 according to the temperature set in the first and second storage chambers 2 and 12, and then the first and second storage cases 4 and 14. The refrigerant is introduced into the first and second accumulators 9 and 19 located in the center of the first and second accumulators.

However, the following problems are pointed out in the structure of the conventional kimchi refrigerator.

That is, since the positions of the first and second accumulators 9 and 19 are located at the centers of the first and second storage cases 4 and 14, the first and second evaporator pipes 6 and 16 and the first and first and second accumulators 9 and 19 are located in the center of the first and second accumulators 4 and 14. Accumulators 9 and 19 are affected by mutual temperature.

For example, when the second storage compartment 2 is used as a freezing compartment and the first storage compartment 12 is used as a refrigerating compartment, a low temperature second accumulator 9 affects the first evaporator pipe 16 and thus the first storage compartment. (12) There is a fear of overcooling. In addition, such a concern may occur even when one side of the first and second storage compartments 2 and 12 is shut down in excess of a preset temperature and the other side is normally operated.

Accordingly, an object of the present invention for solving the above problems is to provide a structure of a direct cooling refrigerator that can prevent the influence of mutual temperature between the left and right evaporator pipe and the left and right accumulator.

1 is a rear view showing the structure of a direct-cooling refrigerator according to the prior art.

2 is a cross-sectional view taken along the line AA ′ of FIG. 1.

Figure 3 is a rear view showing the structure of the direct cooling cold storage according to the present invention.

Explanation of symbols on the main parts of the drawings

52,102 ..... 1st and 2nd storage compartments 52a, 102a .....

52b, 102b ... lower part of the first and second storage compartments 54,104 ....... the first and second storage cases

56,106 ..... 1st and 2nd evaporator pipes

59,109 ..... 1st and 2nd accumulators

A structural feature of the present invention for achieving the above object is, the first and second storage chambers are formed separately stored and stored in the compartment, and the refrigerant flows therein and wound on the outer peripheral surface of the first and second storage chambers A heat exchange cycle including first and second evaporator pipes, and first and second accumulators connected to one end of the first and second evaporator pipes, wherein the first and second accumulators are connected to the first and second evaporator pipes. The first and second accumulators and the first and second evaporator pipes are configured not to be influenced by mutual temperature by installing them so as not to contact any one of the evaporator pipes.

The first and second storage chambers are respectively divided into a first upper, a first lower storage chamber, a second upper storage chamber, and a second lower storage chamber, and the first and second evaporator pipes are respectively formed on the outer circumferential surfaces of the first and second upper storage chambers. Is installed, the first and second accumulators are preferably installed between the first and second lower storage chambers.

According to this configuration, the first and second accumulators are not adjacent to any one side of the first and second evaporator pipes, so that the temperature of the first and second storage chambers is not affected at all by the first and second accumulators. Will not.

Hereinafter, a structure of a direct chiller according to the present invention will be described in detail with reference to a preferred embodiment shown in the drawings.

3 is a rear view showing the structure of the direct-cooling refrigerator according to the present invention. According to this, the first storage chamber 52 and the second storage chamber 102 are shown on the left and right sides in the drawing. As shown in the drawing, the first and second storage chambers 52 and 102 have upper and lower ends, respectively. That is, the first and second storage chambers 52 and 102 are divided into first and second upper storage chambers 52a and 102a and first and second lower storage chambers 52b and 102b, respectively.

However, between the partitioned upper and lower storage chambers 52a, 102a, 52b, and 102b, a passage through which cold air formed in the upper storage chambers 52a and 102a can naturally convection into the lower storage chambers 52b and 102b. Is provided. In addition, one side of the first and second storage compartments (52, 102) consists of a storage compartment that is dedicated to freezing and refrigeration. Therefore, the first and second storage compartments are used for various purposes.

The outer peripheries of the first and second storage chambers 52 and 102 are made of an aluminum storage case. Hereinafter, the storage cases of the first and second storage chambers 52 and 102 are referred to as the first and second storage cases 54 and 104, respectively. The first and second storage cases 54 and 104 are generally made of aluminum.

Further, the first and second evaporator pipes 56 and 106 and the heater wires 57 and 107 are wound on the outer circumferential surfaces of the first and second storage cases 54 and 104, respectively. In detail, the first and second evaporator pipes 56 and 106 are wound around the storage cases 54 and 104 forming the outer circumferential surfaces of the first and second upper storage chambers 52a and 102a, and the first and second lower storage chambers 52b and 102b. The heater wires 57 and 107 are wound around the storage cases 54 and 104 forming the outer circumferential surface of the heater.

Meanwhile, one end of the first and second evaporator pipes 56 and 106 is connected to the first and second accumulators 59 and 109. Accordingly, the refrigerant, which has become relatively high by passing through the first and second evaporator pipes 56 and 106, passes through the first and second accumulators 59 and 109 and is separated into a liquid refrigerant and a gas refrigerant, and only the gas refrigerant is a compressor ( 300 will be introduced.

As shown in the figure, the first and second accumulators 59 and 109 are installed between the first lower storage chamber 52b and the second lower storage chamber 102b. That is, the first and second accumulators 59 and 109 are installed to be substantially spaced apart from the first and second evaporator pipes 56 and 106. Thus, the first and second accumulators 59 and 109 and the first and second evaporator pipes 56 and 106 are not affected by mutual temperature.

Hereinafter, the operation of the direct-cooling refrigerator according to the present invention having the structure as described above will be described in detail with reference to the drawings.

In the direct-cooling refrigerator according to the present invention, the refrigerant flowing out of one compressor 300 flows to two evaporator pipes 56 and 106. The flow path through which the refrigerant flows is selectively determined. That is, the refrigerant selectively flows through the first and second evaporator pipes 56 and 106 in the first and second storage chambers 52 and 102.

For example, when the temperature in the first storage chamber 52 is lower than the preset temperature and the temperature in the second storage chamber 102 is higher than the preset temperature, the refrigerant flows to the second evaporator pipe 106. As the first evaporator pipe 56, the refrigerant does not flow.

In this case, the temperature of the second accumulator 109 which is affected by the temperature of the refrigerant in the second evaporator pipe 106 may be lower than the temperature of the first evaporator pipe 56. Furthermore, if the second storage compartment 102 is used as a freezer compartment, the temperature gap between the second accumulator 109 and the first evaporator pipe 56 will be larger.

However, even in the above case, according to the structure of the direct-cooling refrigerator according to the present invention, since the first and second accumulators 59 and 109 and the first and second evaporator pipes 56 and 106 are substantially spaced apart from each other, they are not affected by mutual temperature. . Therefore, there is no case where the temperature in the first storage chamber 52 is overcooled.

Within the technical scope of the present invention, of course, many other modifications are possible to those skilled in the art.

Therefore, according to the structure of the direct-cooling refrigerator according to the present invention the following effects are expected.

That is, since the first and second accumulators are substantially spaced apart from the first and second evaporator pipes, the first and second accumulators are not affected by the mutual temperature between the first and second accumulator pipes. Therefore, the temperature in the first and second storage chambers is not influenced at all by the first and second accumulators.

Claims (2)

A first and second storage compartments in which a storage is stored and separately partitioned; A heat exchange cycle in which a refrigerant flows and including first and second evaporator pipes wound around outer surfaces of the first and second storage chambers; A first and second accumulators connected to one end of the first and second evaporator pipes; The first and second accumulators and the first and second evaporator pipes are not affected by mutual temperature by installing the first and second accumulators so as not to be in contact with any one of the first and second evaporator pipes. Direct-cooling refrigerator According to claim 1, wherein the first and second storage compartments are respectively divided into a first upper end, a first lower storage compartment and a second upper end, a second lower storage compartment, respectively, the first and second outer compartments of the first and second storage compartments, respectively , 2 evaporator pipe is installed, the first and second accumulators are installed between the first and second lower storage compartments.