KR20140035640A - Evaporator and refrigerating machine using there of - Google Patents

Abstract

The present invention relates to an evaporator and a refrigerating machine using the same. An evaporator according to the present invention comprises: an inlet into which a low-temperature and low-pressure refrigerant expanded by an expansion valve flows; and an outlet from which a heat-exchanged refrigerant is discharged, wherein the inlet and the outlet are formed into one pipeline. Pressure at the outlet formed inside the pipeline is lower than pressure at the inlet formed outside the outlet so that the refrigerant heat-exchanged in the refrigerant flow path of the evaporator at a relatively high pressure, and then quickly discharged from the outlet can allow pressure at the refrigerant of the evaporator to be low, and, as a result, the cooling efficiency of the evaporator can be improved.

Description

Evaporator and refrigeration apparatus using the same {EVAPORATOR AND REFRIGERATING MACHINE USING THERE OF}

The present invention relates to an evaporator and a freezing device using the same, and more particularly, to an evaporator and a freezing device using the same to increase the thermal efficiency of the evaporator heat exchanged with the ambient air as a refrigerant of low temperature and low pressure.

In general, a refrigerating device is a device for freezing and storing food or materials that are relatively fragile. The refrigerating device cools the inside by heat exchange with the surroundings due to a phase change caused by evaporation and compression of the coolant. Cooling is accomplished using a series of refrigerant cycles that repeatedly vaporize and liquefy.

That is, the refrigerating device compresses the refrigerant having a large latent heat of evaporation from the compressor and discharges the refrigerant to a condenser at high temperature and high pressure. It passes through a capillary tube that can control the effect, expands to a low-temperature, low-pressure gas state, and sends the expanded gas-like refrigerant to the evaporator to cool the surroundings through heat exchange (heat absorption) with ambient air. .

As such, the most important thing is to increase the cooling efficiency in a series of processes of compressing, condensing, expanding, and evaporating the refrigerant, that is, cooling the refrigerant cycle. In this case, in order to increase the cooling efficiency, the heat transfer efficiency or the condensation efficiency is increased. To increase the evaporation efficiency.

However, in order to increase the heat transfer efficiency, the condenser must be large, and in order to increase the condensation efficiency, the compression ratio must be increased. Therefore, the compressor must be increased, and the circulation amount of the refrigerant must be increased to increase the evaporation efficiency.

Therefore, the conventional refrigeration unit is to improve the compression efficiency of the compressor to increase the compression efficiency as part of the cooling efficiency, or to expand the heat dissipation area to increase the condensation efficiency of the condenser, that is, install a large number of heat sink fins or install a cooling fan Alternatively, the refrigerant pipe may be spirally formed to extend the length of the refrigerant pipe, and a separate water cooling device may be installed to increase the cooling efficiency, or to expand the surface area of the evaporator in order to increase the cooling efficiency of the evaporator. Improvements have been made to improve the cooling efficiency.

However, since the refrigerating device performs the cooling function by using the heat of vaporization of the refrigerant, the cooling efficiency of the refrigerating device is highly dependent on the heat exchange efficiency of the evaporator, so that the evaporator 1 is shown in FIG. The film is printed in a predetermined shape between the plates 2 to bond the two aluminum plates 2 to each other by hot rolling, and then a high pressure is blown into the film printing portion between the two aluminum plates 2 to expand the refrigerant flow path ( 3) and the refrigerant passage 3 is configured to sequentially progress in a zigzag form from one side to the other side having a predetermined directionality.

One side of the refrigerant passage 3 is formed with an inlet port 4 through which refrigerant is introduced, and the other side of the refrigerant passage 3 is formed with an outlet 5 through which heat exchanged refrigerant is discharged. And the outlet 5 are formed in the same diameter so that the inflow and outflow of the refrigerant is the same.

In the evaporator 1 formed as described above, the inlet port 4 and the outlet port 5 are formed with the same diameter, so that the pressure increases when the refrigerant circulating in the refrigerant passage 3 absorbs heat from the outside air and evaporates. In addition, the pressure increase of the refrigerant increases as the inflow to the outflow side is further increased, and the evaporation efficiency is gradually lowered, resulting in a lowering of the cooling efficiency of the refrigerating device.

In addition, the refrigerant inlet for introducing the refrigerant into the refrigerant passage 3 of the evaporator 1 and the refrigerant outlet for discharging the low-temperature and high-pressure refrigerant through the refrigerant passage 3 are separately provided. Cost increases due to the production of the refrigerant inlet and the refrigerant outlet, which is of course complicated to work, and also has a cumbersome problem by the installation.

An object of the present invention to solve the above problems is to provide an evaporator which can quickly discharge a relatively high pressure refrigerant by evaporation according to heat exchange to increase the cooling efficiency.

Refrigerant flow passage having a predetermined shape and arrangement between the upper and lower plates in the means of the present invention for solving the above problems; An inlet installed in the coolant channel to introduce a coolant; An outlet for outflow of the refrigerant into the refrigerant passage; And the inlet and the outlet are provided as a conduit through which the refrigerant is introduced and discharged into one of the one side or the other side of the refrigerant passage.

In the means of the present invention, the pipe is characterized in that it comprises a double pipe.

In the means of the present invention, the pipe line is provided with an outlet pipe on the inside, characterized in that it is provided with an inlet pipe to the outside of the outlet pipe.

In the means of the present invention, the outlet pipe is characterized in that it comprises a capillary tube.

In the means of the present invention, the inlet pipe is provided with a first fastening end which is fastened to the refrigerant discharge pipe of the expansion valve at the front end and the outlet pipe is formed a second fastening end fastened to the refrigerant recovery pipe of the compressor at the front end It is characterized by including.

In addition, the means of the present invention for solving the above problems is a compressor for compressing the refrigerant into a gas of high temperature and high pressure; A condenser condensing the high temperature and high pressure gas refrigerant compressed by the compressor into a medium temperature high pressure liquid refrigerant while exchanging heat with ambient air; An expansion valve which expands to a low temperature low pressure by expanding a medium temperature high pressure liquid refrigerant condensed in the condenser; A low temperature low pressure refrigerant expanded by the expansion valve and including an evaporator for absorbing heat of ambient air to cool the ambient air, the evaporator having a predetermined shape and arrangement between upper and lower plates; An inlet installed in the coolant channel to introduce a coolant; An outlet for outflow of the refrigerant into the refrigerant passage; And the inlet and the outlet are provided as a conduit through which the refrigerant is introduced and discharged into one of the one side or the other side of the refrigerant passage.

In the means of the present invention, the pipe line is provided with an outlet pipe on the inside, characterized in that it is provided with an inlet pipe to the outside of the outlet pipe.

According to an aspect of the present invention, an inlet and an outlet may be formed as one conduit in an evaporator having an inlet through which a low-temperature low-pressure refrigerant expanded from an expansion valve flows in and an outlet through which heat-exchanged refrigerant flows out. The outlet is formed inside and the inlet is formed outside of the outlet so that the pressure of the outlet is lower than the pressure of the inlet, so that the refrigerant heat exchanged at a relatively high pressure in the refrigerant passage of the evaporator through the outlet. Since it quickly flows out to form a low pressure in the refrigerant passage of the evaporator, it provides an effect of increasing the cooling efficiency of the evaporator.

1 is a perspective view of an evaporator of a conventional refrigeration apparatus
Figure 2 is an installation state diagram of the evaporator of the present invention the refrigerating device
Figure 3 is a perspective view of the evaporator of the present invention the refrigerating device
4 is a cross-sectional view of main parts of the evaporator of the present invention a refrigerating device.
5 is another embodiment of the evaporator of the refrigerator according to the present invention.

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

FIG. 2 is a diagram illustrating an installation of an evaporator of the present invention, and as shown in FIG. 2, the refrigerator 10 freezing and storing food such as a refrigerator or a show case includes a food storage cavity (storage space). A main body case 12 having a body 11, a sealed type having a door 13 for opening and closing the cavity 11 on the front surface of the body case 12, and a low temperature in the open state of the cavity 11; Although divided into an open type for storing, the refrigeration device 10, whether the closed type or the open type, is a refrigeration unit composed of a compressor 14 for cooling the cavity 11, a condenser 15, an expansion valve 16, and an evaporator 17. Means 18 are provided, where the evaporator 17 is installed on the inner top or bottom of the body case 12 to cool the cavity 11.

3 is a perspective view of the evaporator of the refrigerator according to an embodiment of the present invention. As shown in FIG. 3, the evaporator 17 for cooling the cavity 11 of the refrigerator 10 may include a top plate 171 and a bottom plate on a thin metal plate. A film (not shown) is printed in a predetermined shape between 172 to bond the upper and lower plates 171 and 172 to each other by hot rolling, and then the high pressure is blown into the film printing portion to expand the refrigerant. A refrigerant passage 173 is formed.

The coolant channel 173 forms an inlet 174 through which the coolant flows and an outlet 175 through which the coolant flows out, and the inlet 174 and the outlet 175 are formed on either side of the coolant channel 173 or It is formed as a pipe 20 formed together in any one of the other side.

The refrigerant passage 173 is formed to have an approximately elliptical cross section for easy heat transfer of the evaporator 17. That is, the refrigerant passage 173 is possible with the outer circumference of the main body case 12 constituting the cavity 11. Since contacting with a large area is advantageous for heat transfer, it is configured to have an elliptical cross section for increasing the contact area.

And the lower the pressure of the refrigerant evaporator 17, the better the bar, the refrigerant flow path 173 of the evaporator 17 is preferably configured to have a larger volume than the refrigerant discharge pipe of the condenser 15.

Therefore, the evaporator 17 may improve the evaporation efficiency because the refrigerant flowing into the refrigerant passage 173 through the inlet 174 is circulated with a low pressure and circulated to the outlet 175.

In addition, the evaporator 17 allows the refrigerant to flow in and out of the refrigerant passage 173 at one place through the conduit 20, so that the evaporator 17 is separately manufactured by the inlet 174 and the outlet ( Not only can eliminate the hassle to install each 175, but also to reduce the labor and cost of having to process the respective inlet 174 and outlet 175, the refrigeration unit (10) Even when installed inside the main body case 12, the inlet 174 and the outlet 175 formed together in one place can be conveniently installed.

Figure 4 is a cross-sectional view of the main part of the evaporator of the refrigerator according to the present invention, as shown in Figure 4, the pipe line 20 of the evaporator 17 is formed of a double pipe, the double pipe is an outlet pipe ( 21 is formed, and the inlet pipe 22 is formed outside the outlet pipe 21 to be provided.

Here, the outlet pipe 21 is formed as a relatively thin tube compared to the refrigerant passage 173, preferably formed of a capillary tube.

Accordingly, the refrigerant circulating in the refrigerant passage 173 of the evaporator 17 absorbs heat from the outside and evaporates to increase the pressure of the refrigerant, and as the pressure of the refrigerant increases, the evaporation efficiency decreases. The evaporation efficiency gradually decreases toward the outlet 175 side of 173, and as a result, the cooling efficiency of the evaporator 17 decreases.

Thus, the evaporator 17 allows the refrigerant to increase in proportion to the evaporation of the refrigerant toward the outlet 175 so that the evaporator 17 uniformly evaporates at the inlet 174 and the outlet 175 of the refrigerant passage 173. The flow path 173 is formed to be wider to gradually increase in volume toward the outlet 175 side, so that uniform evaporation occurs between the inlet port 174 and the outlet port 175 of the refrigerant channel 173, thereby cooling the evaporator 17. It is maintained so as not to deteriorate.

However, while the refrigerant circulating in the refrigerant passage 173 has the same pressure of the refrigerant flowing from the inlet 174 and the outlet flowing into the outlet 175, the pressure of the refrigerant passage 173 is caused by evaporation of the entire refrigerant. Will rise.

However, the inlet 174 and the outlet 175 of the refrigerant passage 173 are formed as a conduit 20 formed of a double pipe, the outlet pipe coupled to the outlet 175 inside the conduit 20 And an inlet pipe 22 coupled to the inlet 174 on an outer side of the outlet pipe 21, and the outlet pipe 21 is formed of a thin capillary tube to form the coolant path ( The evaporative refrigerant of 173 is allowed to flow through the outlet pipe 21, which is a thin capillary tube.

In this case, when the evaporative refrigerant flowing out through the outlet pipe 21 flows through the pipe, the flow rate is inversely proportional to the cross-sectional area of the pipe, and according to Bernoulli's theorem, the pressure of the fluid is inversely proportional to the speed of the fluid. When the evaporative refrigerant circulated in the refrigerant passage 173 is circulated to a portion whose cross-sectional area becomes small, that is, a thin capillary outlet 21, the velocity of the flow refrigerant is increased, and the pressure is lowered in inverse proportion to the velocity.

Therefore, the pressure of the outlet pipe 21 formed as a capillary tube is relatively low compared to the pressure of the refrigerant passage 173 which is relatively wide, so that the evaporative refrigerant of the refrigerant passage 173 passes through the outlet pipe 21 having a low pressure. Since it flows out at a high speed, the refrigerant flow rate of the refrigerant passage 173 is increased and the pressure of the refrigerant passage 173 is relatively low in inverse proportion to the refrigerant flow rate, the total evaporation pressure of the evaporator 17 This lowers the evaporation efficiency of the evaporator 17 is to be improved to improve the cooling efficiency of the refrigerating device.

5 is another embodiment of the evaporator of the refrigerator according to the present invention. As shown in FIG. 5, descriptions of the same contents as those of FIG. 4 will be omitted.

The inlet pipe 22 has a first fastening end 23 formed at a distal end thereof with a refrigerant discharge pipe of the expansion valve 16 of the cooling means, and the outlet pipe 21 is at the end of the refrigerant of the compressor 14. The second fastening end 24 is formed to be fastened to the recovery pipe.

Therefore, the evaporator 17 is coupled to the refrigerant discharge pipe of the expansion valve 16 by engaging the inlet pipe 22 is formed, the first fastening end 23 is formed at the front end with a separate coupling means In addition, the evaporator 17 is connected to the compressor 14 by fastening the refrigerant recovery pipe of the compressor 14 by means of a separate coupling means and an outlet pipe 21 having a second fastening end 24 formed at the front end thereof. The expansion valve 16 can be easily coupled to eliminate the hassle of installation work.

10; Freezer 11; Cavity
12; Main body case 13; door
14; Compressor 15; Condenser
17; Evaporator 171; top plate
172; Bottom plate 173; Refrigerant flow path
174; Inlet 175; Outlet
20; Pipeline 21; Outflow tube
22; Inlet pipe 23; First decision
24; 2nd executioner

Claims (7)

A refrigerant flow passage having a predetermined shape and arrangement between the upper and lower plates;
An inlet installed in the coolant channel to introduce a coolant;
An outlet for outflow of the refrigerant into the refrigerant passage; And
The inlet and the outlet is an evaporator, characterized in that provided as a channel through which the refrigerant flows in and out of any one side or the other side of the refrigerant passage. The method of claim 1,
The pipe is an evaporator, characterized in that provided as a double pipe. The method of claim 1,
The conduit is provided with an outlet pipe on the inside, and an inlet pipe on the outside of the outlet pipe. The method of claim 3, wherein
The outlet pipe is an evaporator, characterized in that provided with a capillary tube. The method of claim 3, wherein
The inlet pipe is provided with a first fastening end which is fastened to the refrigerant discharge pipe of the expansion valve at the front end, and the outlet pipe is characterized by having a second fastening end which is fastened with the refrigerant recovery pipe of the compressor at the front end. evaporator. A compressor for compressing the refrigerant into a gas of high temperature and high pressure;
A condenser condensing the high temperature and high pressure gas refrigerant compressed by the compressor into a medium temperature high pressure liquid refrigerant while exchanging heat with ambient air;
An expansion valve which expands to a low temperature low pressure by expanding a medium temperature high pressure liquid refrigerant condensed in the condenser;
It includes an evaporator for cooling the ambient air by absorbing the heat of the ambient air to the refrigerant of low temperature low pressure expanded from the expansion valve,
The evaporator has a refrigerant passage having a predetermined shape and arrangement between the upper and lower plates; An inlet installed in the coolant channel to introduce a coolant;
An outlet for outflow of the refrigerant into the refrigerant passage; And
The inlet and the outlet is an evaporator and a refrigerating device using the same, characterized in that the refrigerant flows in and out of one of the one side or the other side of the refrigerant passage is provided. The method according to claim 6,
The pipe is provided with an outlet pipe on the inside, the evaporator characterized in that it comprises an inlet pipe to the outside of the outlet pipe and a refrigeration apparatus using the same.

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