RU2373464C2 - Anti-frost evaporation tube of refrigerator with drawers - Google Patents

Abstract

FIELD: heating systems.

SUBSTANCE: anti-frost evaporation tube of refrigerator with drawers consists of internal housing wherein there provided is food storage compartment for arranging drawer-container, and in the latter, low temperature is maintained by means of evaporation tube for cooling agent circulation, which is located around external part of internal housing. Evaporation tube includes curved parts located on both side surfaces of internal housing and straight tube part located on upper surface of internal housing and connected to curved tube parts.

EFFECT: use of this invention allows eliminating frost formation on roof surface of refrigerator internal housing.

5 cl, 7 dwg

Description

BACKGROUND OF THE INVENTION

1. The technical field to which the invention relates.

The present invention relates to an evaporator tube of a refrigerator with drawers, and more particularly, to an anti-yoke evaporator tube of a refrigerator with drawers, in which the construction of the evaporator tube is improved and prevents the formation of frost on the ceiling in the refrigerator food storage chamber, and the operating mode of the refrigerator can be more precisely controlled with using a more accurate determination of the state of the inside of the food storage chamber.

2. Description of the prior art

Basically, the refrigerator is designed to extend the shelf life of food products by circulating the refrigerant inside it. Recently, various refrigerators have been created according to their purpose. For such special purposes, refrigerators have been created that allow for simple storage of products and have the function of ripening products.

In accordance with methods for opening doors, such refrigerators are divided into a refrigerator with an opening upper part, when a food product is placed or removed from the refrigerator through its upper part, and a refrigerator with a drawer in which the door is made in the form of a box.

1 is a perspective view of a conventional drawer refrigerator, and FIG. 2 is a view showing an internal configuration of a drawer refrigerator in accordance with the prior art.

As shown in FIGS. 1 and 2, the prior art refrigerator 10 comprises an outer case 20 in the form of a rectangular box and inner cases 30 mounted in the outer case 20 and forming a plurality of food storage chambers 32. Corresponding food storage chambers 32 formed in the inner housings 30 are independently thermally controlled by the control device 22 installed in the upper front part of the outer shell 20.

In addition, a predetermined gap is provided between the outer and inner cases 20 and 30, and this gap is filled with insulating material 25. Moreover, a drawer-container 40 for storing products is located in the food storage chamber 32 of the inner case 30. Products such as fruits, vegetables, meat and processed foods are stored directly in the drawer-container 40 for storing products or are stored in an additional inner container 42 installed in the drawer-container for storing food.

The drawer-container 40, thus configured, includes a door 44 mounted on its front side, and retracts or extends from the inner housing 30 to close or open the food storage chamber 32.

To this end, movable guides 47 are mounted on both sides of the drawer-container 40 in the horizontal direction and are slidably supported on the fixed guides 37 mounted on the food storage chamber 32 of the inner case 30.

FIG. 3 is a perspective view of an inner case and an evaporator tube of a drawer refrigerator in accordance with the prior art, and FIG. 4 is a perspective view of a spatial separation of parts showing a state in which the evaporator tube of FIG. 3 is separated from the inner corps. The design and operation of the inner casing and the evaporation tube will be described in detail with reference to FIGS. 3 and 4.

An evaporator comprising an evaporator tube 34 through which refrigerant circulates to store products stored in the food storage chamber 32 at a low temperature is located on the outside of the inner case 30. In addition, a compressor 29 for injecting refrigerant and a refrigeration circulation system for supplying or collecting refrigerant to and from the evaporator tube 34 are installed under the inner housing 30.

In this case, the inner case 30 is made of aluminum to increase the heat transfer rate in it, and the evaporation tube 34 is formed in such a way that it is located on three outer surfaces, i.e. on both side surfaces and the upper surface of the inner housing 30.

The prior art refrigerator 10 with drawers configured in this way includes a temperature sensor 38 or a similar device to maintain optimal storage conditions for products in the food storage chamber. To this end, to date, the sensor 38 has been located between the evaporation tubes 34 located on the upper surface of the inner case 30, and a fastener 39 for securing the sensor 38 on the inner case was placed transversely above the adjacent evaporator tubes 34.

When the evaporator tube 34 of a conventional drawer refrigerator 10 configured as described above has been used for a long time, the products stored in the upper part of the container drawer 40 are very cooled and are thus frozen by the evaporator tube 34 mounted on the ceiling surface of the inner case 30, and as a result they deteriorate.

In addition, since hoarfrost forms on the ceiling surface of the inner case 30, interference with the drawer-container 40 creates interference from the side of the inner case 30 when the container is pushed in or out of the inner case. In addition, since the drawer-container 40 quickly freezes to the inner case 30, the drawer-container 40 cannot smoothly open or close.

In addition, since the frost formed on the ceiling surface of the inner case 30 impedes the transfer of heat into the inner case and thus reduces the thermal efficiency of the refrigerator, it is necessary to remove the frost.

On the other hand, when the user defrosts the refrigerator, the frost turns into water, which flows down into the drawer-container 40. Therefore, the products stored in the drawer-container 40 are damaged and deteriorated.

These problems are a consequence of the formation of frost on the surfaces of the inner shell 30. Thus, measures must be taken to prevent the formation of frost on the inner surfaces of the inner shell 30. For this purpose, attempts have been made to prevent the formation of frost by improving the design of the evaporator tube. More specifically, a design improvement is required in which sensors are mounted to more accurately measure the temperature in the food storage chamber.

SUMMARY OF THE INVENTION

The present invention is directed to solving these problems regarding the state of the art. Therefore, it is an object of the present invention to provide an anti-frost evaporator tube of a refrigerator with drawers, in which by preventing the formation of frost on the ceiling surface of the inner case by improving the design of the evaporator tube mounted on the inner case, there is strong cooling and food spoilage, as well as food spoilage as a result the transformation of frost into water can be prevented, and the box-container can more smoothly open or close, and in which The rum can be set to a more accurate operating mode and temperature fluctuations in the food storage chamber can be eliminated by using a sensor installed to more accurately determine the food storage chamber mode.

In accordance with an aspect of the present invention, to achieve this goal, there is provided a non-frosty evaporator tube of a refrigerator with drawers, including an inner case, in which a food storage chamber is formed to accommodate a drawer-container for storing products, and by means of an evaporation tube placed on the outer surface of the inner case , in the drawer-container for storing food, low temperature is maintained, while the evaporation tube contains bent parts of the tube located on both side surfaces of the inner case, and a straight part of the tube located on the upper surface of the inner case and connected to the curved parts of the tube.

Preferably, each of the curved portions of the tube includes a large number of closely spaced straight sections of the tube. More preferably, the evaporation area of the curved portions of the tube located on the outlet side from where the refrigerant exits is larger than the area of the curved portions of the tube located on the inlet side where the refrigerant enters. The anti-frost evaporator tube may further include an additional curved part of the tube on which a sensor is mounted to measure the state of the food storage chamber, said additional curved part of the tube being formed on a portion of the straight part of the tube. Preferably, the additional curved part of the tube includes additional straight sections of the tube parallel to each other, and an additional curved section of the tube connected to additional straight sections of the tube. In addition, the fastener may be mounted transversely above parallel parallel straight pipe sections to secure the sensor.

Brief Description of the Drawings

These and other objectives, features and advantages of the present invention will become apparent when reading the following description of preferred embodiments in combination with the accompanying drawings, in which:

figure 1 depicts a perspective view of a conventional refrigerator with drawers;

figure 2 is a view showing the internal configuration of the refrigerator of the prior art;

figure 3 is a perspective view of the inner case and the evaporator tube of the refrigerator with drawers of the prior art;

4 is a perspective view with a spatial separation of the parts, showing the position in which the evaporation tube in figure 3 is separated from the inner housing;

5 is a view showing an internal configuration of a drawer refrigerator in accordance with the present invention;

6 is a perspective view of the inner housing and the evaporation tube with anti-friction design used in it;

7 is a perspective view with a spatial separation of the parts, showing the position in which the evaporation tube in Fig.6 is separated from the inner housing.

Description of a preferred embodiment of the invention

Next, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

5 is a view showing an internal configuration of a drawer refrigerator in accordance with the present invention.

As shown in FIG. 5, the drawer refrigerator 50 comprises an outer case 60 in the form of a rectangular box that defines the exterior of the refrigerator and an inner case 70 in the form of a box with an open front surface that is installed in the outer case 60 to form a large number of chambers 72 food storage. The respective food storage chambers 72 are independently thermally controlled by a control device 62 mounted in the upper front part of the outer casing 60.

In addition, the outer and inner housings 60 and 70 are connected to each other with a predetermined gap, and the insulating material 65 fills the gap to maintain a constant temperature in the food storage chambers 72.

A drawer-container 90 is located in the food storage chamber 72 of the inner case 70. Products such as fruits, vegetables, meat and processed foods are stored directly in the drawer-container 90 for storing food or are stored in an additional inner container 92 installed in drawer-container 90 for storing food.

The container drawer 90 includes a door 94 mounted on its front side, and can be retracted or extended from the inner housing 70 to close or open the food storage chamber 72.

To this end, movable guides 97 are mounted on both sides of the container drawer 90 in the horizontal direction, while the fixed guides 77 corresponding to the movable guides 97 are mounted on the food storage chamber 72 of the inner housing 70 to support the sliding of the container drawer 90 and the direction of the movable guides 97 along the fixed guides 77 when the drawer-container is pushed in or out of the inner case.

Mechanical devices including a compressor 69, a condenser, and a refrigerant accumulator (not shown in this figure) are installed in a compartment located under the inner housing 70. A condenser (not shown) is connected to the outlet of the compressor 69, and an expansion valve and an evaporator (not shown) are also connected in series with the compressor output.

The evaporator comprises an evaporation tube 74 located on the outer surface of the inner case 70. The refrigerant supplied by the pump from the compressor 69 is circulated through the evaporator tube 74 and cools the inside of the inner case 70.

6 depicts a perspective view of the inner casing and the evaporation tube with anti-frost construction used in it; and FIG. 7 is an exploded perspective view showing a state in which the evaporator tube of FIG. 6 is separated from the inner case.

As shown in FIGS. 6 and 7, the evaporation tube 74 is tightly configured on both side surfaces of the inner housing 70 and has a sparse configuration on the upper surface of the inner housing 70.

To this end, the evaporation tube 74 is composed of a curved tube portion 75 formed on both side surfaces of the inner casing 70 and a straight tube portion 76 formed on the upper surface of the inner casing 70. The curved tube portion 75 contains a large number of straight tube sections 75a tightly spaced on the lateral surfaces of the inner casing 70, and a large number of semicircular curved tube sections 75b connected to the ends of the straight tube sections 75a for liquid to pass through the straight and curved sections of the tube ubki. Meanwhile, the straight portion 76 of the tube is loose. By changing the size of the cross section and the number of bent and straight parts 75 and 76 of the tube, the cooling capacity can be adjusted.

In addition, the sensor 78 measuring the temperature of the food storage chamber for measuring the state of the food storage chamber is installed on the side of the inner housing 70. To this end, a mounting location 80 for the sensor into which the sensor 78 is mounted is formed on the side of the vaporization tube 74.

More specifically, the sensor mounting location 80 is formed on the side of the straight tube portion 76 to provide tight contact with the upper surface of the inner housing 70 so that the sensor 78 can determine the state of the upper portion of the food storage chamber 72. To this end, a sensor mounting location 80 is provided with an additional curved tube portion 85 formed on the side of the straight tube portion 76.

In this embodiment of the present invention, an additional curved tube portion 85 is formed in the center of the upper surface of the inner housing 70. In this case, the additional curved tube portion 85 is composed of two additional straight tube sections 85 parallel to each other and an additional curved portion 85b connected for communication with the ends of the respective straight sections 85a of the tube. In addition, the fastener 79 is mounted transversely above the parallel additional straight pipe sections 85a. A fastener 79 is used to fasten the sensor 78 to the additional curved portion 85 of the tube so that the sensor 78 is fixed to the lower surface of the fastener 79 and then brought into close contact with the upper surface of the inner housing 70.

In addition, the curved portions of the tube located on the side surfaces of the inner casing 70 are formed such that the curved portion of the tube located on the outlet side of the refrigerant is larger than the curved portion of the tube located on the inlet side of the refrigerant, taking into account their evaporation area. In this case, a larger evaporation area means a larger contact area of the inner housing 70 from the outside. More specifically, the curved portion of the tube located on the outlet side from where the refrigerant exits is longer than the curved portion of the tube located on the inlet side where the refrigerant enters. That is, the refrigerant circulating in the curved part of the tube 75 on the inlet side can sufficiently cool the food storage chamber 72 due to its high cooling capacity, although the evaporation area of the curved part of the tube in the inlet side is smaller, while the refrigerant circulating in the curved part of the tube 75 on the output side, has a relatively low cooling capacity as a result of loss of cooling ability when passing through the curved portion 75 of the tube on the input side and the straight part of the tube. Accordingly, the evaporation area of the curved portion 75 of the tube on the output side is increased so that its cooling ability is controlled in the same manner as that on the curved portion 75 of the tube on the inlet side. In addition, to achieve a more constant cooling capacity, the curved portion 75 of the tube on the output side can be extended to part of the upper surface of the inner housing 70.

As described above, it is possible to reduce temperature fluctuations on the right and left side of the food storage chamber 72, and also operate the refrigerator in an optimal manner by adjusting the length of the curved portion of the tube in accordance with the cooling ability of the refrigerant.

Meanwhile, a defrosting device (not shown) for defrosting the food storage chamber 72 is mounted on the side of the inner case 70.

The operation of the anti-frost evaporator tube of the refrigerator with drawers in accordance with the present invention configured in this way will be described as follows.

First of all, when the refrigerator is turned on by the control device 62, the compressor 69 starts to operate and then delivers the high pressure compressed refrigerant to the condenser. The refrigerant fed to the condenser generates heat and, thus, turns into a phase with high pressure and low temperature and, then, is fed to the expansion valve. Then the refrigerant supplied to the expansion valve expands instantly and thus turns into a phase with low pressure and low temperature when supplied to the evaporator. The refrigerant supplied to the evaporator carries out heat exchange with the food storage chamber 72 in the inner case 70 while passing through the vaporization tube 74 located around the inner case 70. At this time, the container drawer 90 installed in the food storage chamber 72 and the products stored in the drawer-container 90, are cooled so that the products can be kept fresh for a long time.

In addition, heat exchange occurs between the food storage chamber 72 in the inner case 70 and the curved tube parts 75 mounted on the side surfaces of the inner case and a straight part 76 of the tube mounted on the upper surface of the inner case and connected to the curved part of the tube. A heat transfer effect is also present in the food storage chamber 72 due to air circulation in it.

During operation of the refrigerator with drawers, as described above, the ceiling surface of the inner case 70 is not very cooled and, thus, the products stored in the upper part of the drawer-container 90 can be stored in not frozen and fresh form.

In addition, since hoarfrost does not form on the ceiling surface of the inner case 70, the container drawer 90 does not touch the hoarfrost and is thus controlled smoothly when the container drawer slides in or out of the inner case.

In addition, since the sensor 78, which is firmly installed in the sensor mounting location 80 on the upper surface of the inner case by the fastener 79, can measure the state in the food storage chamber and then send information about the measured state to the control device 62, it is possible to operate the refrigerator 50 in optimal mode.

According to the present invention, thus configured, the design of the anti-frost evaporator tube of the drawer mounted on the inner case is improved in such a way that heat exchange in the food storage chamber formed in the inner case can be carried out efficiently. Therefore, since the ceiling surface of the inner case is not cooled very much, the products stored in the upper part of the food storage chamber cannot be frozen. In addition, since hoarfrost does not form on the ceiling surface, the container drawer can slide in or out of the inner case smoothly. Moreover, since hoarfrost does not form on the ceiling surface of the inner casing, water that may be formed when the frost formed on the inner surfaces of the inner casing melts does not enter the container drawer. Therefore, the products stored in the drawer-container do not deteriorate from the resulting water, and, in addition, the working environment remains clean, and the heat transfer capacity increases. In addition, since the evaporation area of the curved parts of the tube located on the outlet side from where the refrigerant exits is larger than the evaporation area of the curved parts of the tube located on the inlet side where the refrigerant enters, temperature fluctuations on the right and left sides of the food storage chamber can be reduced and Thus, the refrigerator can work optimally. Moreover, since the sensor is installed in such a way that it can measure the temperature in the food storage chamber more accurately, the state of the food storage chamber can be accurately determined and thus the refrigerator can also operate in optimal operating mode.

Although the anti-frosty evaporator tube of the drawer refrigerator in accordance with the present invention has been described with reference to the accompanying drawings, the present invention is not limited to the embodiment described with the drawings. Those skilled in the art will appreciate that various modifications and changes are possible within the scope of the appended claims. It is also possible to further increase the cooling capacity by adding a curved portion of the tube on the side of the straight portion of the tube. You must also understand that the curved and straight sections of the tube, described in the description of the present invention, are only shown in accordance with their layout, and it is not meant that they are mathematically accurately represented by straight or curved lines. As an example, straight tube sections located on the upper surface of the inner case may include several curved tube sections to further increase the cooling capacity of the evaporator tube. In addition, said sensor is a sensor for measuring the temperature in the food storage chamber, but another sensor having a humidity measurement function or the like may also be installed to provide better performance.

Claims (5)

1. Anti-frost evaporator tube of a refrigerator with drawers containing an inner case, in which a food storage chamber is formed to accommodate a container drawer, and the drawer-container is kept at a low temperature by means of an evaporator tube for refrigerant circulation located around the outer part of the inner case wherein the evaporation tube comprises curved portions of the tube located on both side surfaces of the inner case; and a straight portion of the tube located on the upper surface of the inner housing and connected to the curved portions of the tube. 2. Anti-frost evaporator tube according to claim 1, in which each of the curved parts of the tube contains many densely spaced straight sections of the tube and semicircular curved sections of the tube connected to both ends of the straight sections of the tube. 3. Anti-frost evaporator tube according to claim 1 or 2, in which the area of evaporation of the curved parts of the tube located on the output side, where the refrigerant comes from, is larger than the area of evaporation of the curved parts of the tube located on the inlet side, where the refrigerant enters. 4. Anti-frost evaporator tube according to claim 1 or 2, containing an additional curved part of the tube, in which a sensor is installed to measure the state of the food storage chamber, while the specified additional curved part of the tube is formed on the straight portion of the tube. 5. The anti-frost evaporative tube according to claim 4, in which the additional curved part of the tube contains additional straight sections of the tube parallel to each other, and an additional curved section of the tube connected to additional direct sections of the tube, and the fastener is located transversely above the parallel straight sections of the tube to fix the sensor on it.

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