KR20050062236A - Structure for flowing of cool air in refrigerator - Google Patents

Abstract

The present invention relates to a refrigerator of the present invention, in particular, by allowing the cold air discharged into the freezer compartment and the refrigerating compartment to be uniformly provided to all parts of the inside of the refrigerator structure that can achieve a uniform refrigeration and uniform refrigeration flow of the refrigerator It is intended to provide.

To this end, the present invention has a cold air duct for the freezer compartment having at least one cold air outlet, the cold air duct for receiving the cold air from the space provided with the evaporator constituting the freezing cycle supplied to the freezer compartment and the refrigerating compartment; And, there is provided a cold air flow structure of the refrigerator comprising: a flow separation unit: provided in a portion where at least one cold air outlet hole of each cold air duct is formed to separate the flow of the discharged cold air into at least two or more flows.

Description

Structure for flowing of cool air in refrigerator

The present invention relates to a refrigerator, and more particularly, to a cold air flow structure of a refrigerator for supplying cold air to a freezer compartment or a refrigerating compartment.

In general, the refrigerator is one of the necessities of life as a device that keeps food fresh for a certain period of time by lowering the inside of the refrigerator as the refrigerant (working fluid) repeats the refrigeration cycle of compression, condensation, expansion and evaporation.

Such a refrigerator includes a compressor for raising / heating a low temperature / low pressure gas refrigerant to a high temperature / high pressure gas refrigerant, a condenser for condensing the refrigerant introduced from the compressor by outside air, and a narrow diameter compared to the diameter of other parts. It consists of an expansion valve for reducing the refrigerant introduced from the condenser, and the evaporator which absorbs the heat in the refrigerator as the refrigerant passing through the expansion valve in a low pressure state as a basic component constitutes a refrigeration cycle.

Hereinafter, with reference to the accompanying drawings will be described the structure and operation of a typical double door refrigerator.

First, as shown in FIGS. 1 to 3, the refrigerator includes a main body 10, a barrier 20, a freezing chamber 30 and a refrigerating chamber 40, a cold air generator, and a cold air supply unit. do.

Here, the barrier 20 is provided to form the freezer compartment 30 and the refrigerating compartment 40 in a state partitioned from each other by separating the inside of the main body 10 into left and right spaces, and inside the refrigerating compartment cold air duct in which cold air flows. 50 is provided.

In this case, a first cold air inflow hole 21 through which the cold air flowing through the cold air supply part flows is formed on a surface of the side of the barrier 20 in which the cold air supply part is located. A plurality of first cold air outlet holes 51 through which cold air flows out in communication with the refrigerating chamber cold air duct 50 is formed on the side of the side where the refrigerating compartment 40 is located.

In addition, a cold air communication hole 22 communicating with the cold air flowing through the refrigerating compartment 40 to the freezing compartment 30 is formed at the lower side of the barrier 20.

The cold air generating device includes an evaporator 11 and is generally provided on the rear side space of the freezing compartment 30. A compressor, a condenser, etc. (not shown) constituting a refrigeration cycle together with the evaporator 11 is provided in the machine room 12, which is the bottom of the main body 10.

At this time, the freezing chamber 30 forms a rear wall surface and is partitioned from the space where the cold air generating device is provided by the freezing chamber cold air duct 60 formed to allow the flow of cold air therein.

A plurality of second cold air outlet holes 61 are formed in the freezing compartment cold air duct 60 so that cold air generated by the cold air generating device flows into the freezing compartment 30, and a lower side of the freezing compartment cold air duct 60 is formed. A second cold air inflow hole 62 into which cold air flowing through the freezing chamber 30 flows into a space provided with the cold air generator is formed.

The cold air supply unit is provided at an upper side of a space where the cold air generator is provided, and includes a blower fan 71 for forced circulation of cold air.

At this time, a freezing chamber communication hole 63 communicating with the freezing chamber cold air duct 60 is formed at a portion of the freezing chamber cold air duct 60 where the blowing fan 71 is located.

In addition, a damper 81 is provided in an upper space of the refrigerating chamber 40 to transmit cold air while being in communication with the first cold air inlet 21 of the barrier 20, and to adjust a supply amount of the cold air. The control box 80 is provided.

At this time, the control box 80 is formed so as to communicate with the refrigerating chamber cold air duct 50 in the barrier 20, at least one or more third cold air outlet hole 82 directly supplying cold air to the interior space of the refrigerating chamber 30. )

Hereinafter, the cold air circulation process by the operation of the above-described conventional double door refrigerator will be described in more detail.

First, the air forcedly circulated by the driving of the blower fan 71 passes through the evaporator 11 constituting the refrigeration cycle, so that the temperature is drastically lowered to form a cold air state. Subsequently, the cold air is formed in the freezing chamber cold air duct 60. In addition to passing through the freezer compartment communication hole (63), it passes through the first cold air inlet hole (21) formed in the barrier (20).

In this process, the cold air introduced into the freezer compartment cold air duct 60 through the freezer compartment communication hole 63 flows through the freezer compartment cold air duct 60 and each second cold air outlet hole formed in the freezer compartment cold air duct 60 ( 61 is supplied into the freezer compartment 30 through.

In addition, the cold air passing through the first cold air inlet 21 formed in the barrier 20 flows to the control box 80.

At this time, some of the cold air flowing through the control box 80 is directly supplied to the refrigerating chamber 40 through each of the third cold air outlet hole 82 formed in the control box 80 and the other part of the refrigerating chamber cold air duct While flowing (50), it is supplied to the refrigerating chamber (40) through each of the second cold air outlet holes (61).

In addition, the cold air in which the food stored in the refrigerating compartment 40 is refrigerated while the refrigerating compartment 40 flows is provided in the freezing compartment through the cold air communication hole 22 of the barrier 20 formed in the bottom side space of the refrigerating compartment 40. 30 flows through the second cold air inlet hole 62 of the freezer compartment cold air duct 60 formed in the bottom space of the freezer compartment 30 to the space equipped with the cold air generating device, and the evaporator 11. Will pass).

However, in the structure of the conventional double door refrigerator as described above, the size of each cold air outlet hole 51, 61, 82 through which cold air is discharged into the freezer compartment 30 and the refrigerating compartment 40 is relatively larger than the volume of the inside of the refrigerator. Since it is very small, there is a problem that the distribution of cold air in the freezer compartment 30 and the refrigerating compartment 40 is not uniform.

In particular, since the cold air discharged into the freezing chamber 30 and the refrigerating chamber 40 is discharged intensively only in the direction in which the cold air outlet holes 51, 61, and 82 are formed, uniform supply cannot be made to each part of the refrigerator. Have problems.

That is, the concentration of cold air occurs only in the localized portion, so that the uniform refrigeration or the uniform refrigeration was not performed.

The present invention has been made in order to solve the above-mentioned conventional problems, by allowing the cold air discharged into the freezer compartment and the refrigerating compartment to be uniformly provided to all the parts of the refrigerator of the refrigerator that can achieve uniform freezing and uniform refrigeration The purpose is to provide a structure for cold air flow.

In order to achieve the above object, according to the aspect of the present invention, the cold air duct and refrigeration unit for receiving the cold air from the space provided with the evaporator constituting the freezing cycle having at least one cold air outlet, and supplying to the freezer compartment and the refrigerating compartment Practical cold air duct; In addition, the cold air flow structure of the refrigerator comprises a flow separation unit: provided in a portion where at least one cold air outlet hole of each cold air duct is formed to separate the flow of the discharged cold air into at least two or more flows.

Hereinafter, with reference to the accompanying Figures 4 to 11 will be described the most preferred embodiments of the present invention.

First, FIG. 4 is a structural view schematically showing the internal structure of the refrigerator to which the fluid separation unit of the present invention is applied, and FIG. 5 is a state diagram showing the installation state of the fluid separation unit in detail.

That is, according to the present invention, at least one portion of the cold air duct 50 for the refrigerating chamber is formed, and at least one portion of the cold air duct 60 for the cold storage duct 60 is formed. It is to be provided with a flow separator 200 in each.

Of course, the flow separation unit 200 may be provided at a portion where the third cold air outlet hole 82 of the control box 80 is formed, as shown.

Here, the flow separation unit 200 through the first cold air outlet hole 51, the second cold air outlet hole 61 and the third cold air outlet hole 82 to the freezing chamber 30 and the refrigerating chamber 40. The flow of cold air discharged is separated into at least two flows.

The flow separation unit 200 is installed in a direction perpendicular to the flow direction of the cold air to block the cold air discharged through each of the cold air outlet holes (51, 61, 82) as shown in FIG.

In the first embodiment of the present invention, the flow separation unit 200 is characterized in that the plate is a flat plate having a constant thickness but a flat, the flow separation unit 200 of the above-described shape is each cold air outlet hole (51) And 61,82 are configured to remain fixed at the site where they are formed.

That is, the cold air flowing along each cold air duct (50, 60) hits the surface of the flow separation unit 200 immediately before being discharged through each cold air outlet hole (51, 61, 82) chaos (Chaos) of an abnormal state To form a flow.

At this time, the chaos flow includes a large number of small and large vortex (vortex), the cold air discharged through each of the cold air outlet holes (51, 61, 82) under the influence of the freezer compartment 30 and the cold compartment (40) It swings to the left and right in the inner side so that it can spread to all parts of the chamber.

This is because, due to the presence of the flow separation unit 200 inverse pressure gradient (adverse pressure gradient) is formed on the flow boundary layer (flow boundary layer) formed on the surface of the flow separation unit 200, thereby each cold air duct Since the cold air flowing along the (50, 60) causes separation at one point of the flow separation unit 200, a vortex is formed after the separation point and the back of the flow separation unit (200) This is because the vortices formed on both sides of the surface facing the ball enable the formation of a flow that progresses while vibrating.

That is, two vortices are largely formed on both sides of the rear side of the flow separator 200, and these two vortices have a constant frequency determined according to the flow inflow rate and the shape and dimensions of the flow separator 200. Its size and intensity change, and thus the discharged flow swings from side to side and swings.

The flow separation unit 200 may be configured to form a separate flow path only in a portion of each cold air duct (50, 60) as in this embodiment or may be configured to cover a wider length, but of the present invention To the extent that the purpose is achieved, it is sufficient and only desirable that a separate flow path be formed in only a part of each cold air duct 50, 60.

On the other hand, in order to obtain the maximum flow diffusion effect by vibrating and advancing flow generated by the interference between the two vortices, the cold air outlet holes 51, 61, and 82 are positioned immediately after the point where the interference between the two vortices occurs. This is preferable.

That is, it is preferable to position the cold air outlet holes 51, 61, 82 of each cold air duct 50, 60 adjacent to the point where two separate flow paths formed by the flow separation unit 200 meet.

To this end, in the embodiment of the present invention, the distance between the flow separation unit 200 and the cold air outlet holes 51, 61, 82 of the respective cold air ducts 50, 60 is the cold air outlet holes 51, 61, 82. It is proposed to set approximately the same or smaller than the opening width of.

According to the structure according to the embodiment of the present invention, the flow path from the both sides of the flow separation unit 200 to the cold air outlet holes (51, 61, 82) acts as a kind of nozzle (separated flow path) Each flowing flow is accelerated to form two jets.

At this time, the two jets collide with each other in a straight line or at a predetermined angle to raise static pressure above atmospheric pressure immediately before a portion formed in the cold air outlet holes 51, 61, 82, and also unsteady. form a flow of state.

This, together with the vortex formation by peeling, forms two more powerful vortices on both sides of the rear surface of the flow separator 200.

Along with this, the two vortices are changed in magnitude and intensity at a constant frequency determined by the inflow velocity and the thickness of the flow separator 200 as described above, and the static pressure is changed accordingly. The swinging flow passes through the cold air outlet holes 51, 61, and 82 to be discharged into the refrigerator.

Hereinafter, the cold air supply process to the freezing compartment 30 and the refrigerating compartment 40 by the structure according to the first embodiment of the present invention will be described in detail.

First, the cold air whose temperature is rapidly reduced while passing through the evaporator 11 flows to the freezing chamber cold air duct 60 and the refrigerating chamber cold air duct 50 by driving the blower fan 71.

In addition, the cold air flows through each of the cold air ducts 50 and 60 and the first cold air outlet 51 and the second cold air outlet 61 and the third cold air ducts 50 and 60 formed therein. It is discharged into the freezer chamber 30 and the refrigerating chamber 40 through the cold air outlet hole 82.

At this time, since each of the cold air outlet holes 51, 61, and 82 are formed with a flow separator 200, the discharged cold air collides with the flow separator 200 during its discharge. The vortex is generated, and as described above, the flow that vibrates by the vortex is formed.

In particular, the two flows respectively forming the vortices on both sides of the rear surface of the flow separation unit 200 after passing through both sides of the flow separation unit 200 before passing through the respective cold air outlet holes (51, 61, 82) By colliding with each other, a stronger vortex is formed, and the swing width of the discharged cold air is wider.

Therefore, the cold air discharged into the refrigerator is not only concentrated in a specific direction but is discharged in a dispersed state toward each part of the refrigerator, thereby allowing even cold air to be supplied.

On the other hand, Figure 7 is shown the structure according to the second embodiment of the present invention.

That is, in the second embodiment of the present invention, the portions in which the cold air outlet holes 51, 61, and 82 of each of the cold air ducts 50 and 60 are formed, in particular, the portions in which the flow separation unit 200 is mounted are compared with other portions. It is expanded to have a large space.

In the following, the site where the expansion of the conduit is made is called expansion unit 300.

The reason for forming the expansion unit 300 as described above is that the cold air has a relatively high flow rate while hitting the flow separation unit 200 while having an appropriate flow rate compared to the hitting the flow separation unit 200 is uniform This is because the dispersion is possible and the loss due to the resistance of the flow can be further reduced.

In particular, in order to obtain the effect of the optimal cold air dispersion, the width D ₃ of the expansion part 300 is preferably formed to be about 2 to 2.5 times the width D ₀ of the cold air ducts 50 and 60. The length H ₂ of the expansion pipe 300 is more preferably about 1 to 1.2 times the width D ₀ of the cold air ducts 50 and 60.

In addition, the width D ₀ of each of the cold air ducts 50 and 60 and the width D of the flow separation unit 200 and the width D ₂ of the cold air outlet holes 51, 61, and 82 are equal. It is preferable.

Of course, the distance (H ₁ ) between the flow separation unit 200 and each cold air outlet hole (51, 61, 82) is about 0.5 times the width (D ₀ ) of each of the cold air duct (50, 60) It is desirable to achieve.

On the other hand, Figure 8 is shown the structure according to the third embodiment of the present invention.

The structure of the third embodiment is to improve the expansion unit 300 according to the second embodiment of the present invention so that the energy loss due to the flow resistance of cold air can be reduced.

That is, in order to prevent a sudden decrease in the flow rate that may be caused by the rapid expansion of the pipe line, the portion connected to the cold air duct (50, 60) of the expansion pipe 300 from the connected cold air outlet holes (51, 61, 82) ) Is formed to be inclined so as to gradually expand toward the side formed.

Therefore, the structure according to the third embodiment of the present invention can reduce the energy loss due to the flow resistance.

Meanwhile, FIGS. 9A to 9C illustrate various embodiments of the flow separator 200 according to the first embodiment of the present invention.

That is, when the flow separation unit 200 is formed in a flat plate type, a large amount of energy loss may occur due to a large resistance to flow of cold air.

At this time, the air resistance coefficient of the flat plate is 2.0 as known.

Therefore, it is necessary to select a flow separator 200 having a smaller drag coefficient.

Accordingly, the flow separation unit 210 according to another embodiment of the present invention is formed to be convexly rounded in the opposite direction to the flow direction of the cold air toward the center side, as shown in Figure 9a.

In this case, the air resistance coefficient of the flow separator 210 is approximately 1.40.

In addition, the flow separation unit 220 according to another embodiment of the present invention is formed to be convexly bent in the opposite direction to the flow direction of the cold air toward the center side as shown in Figure 9b.

In this case, the air resistance coefficient of the flow separator 220 is approximately 1.20.

In addition, the flow separator 230 according to another embodiment of the present invention is convexly rounded in the same direction as the flow direction of the cold air and in the opposite direction to the flow direction of the cold air as it goes toward the center side, as shown in FIG. 9C. It is proposed to form an elliptical shape as a whole.

As described above, in the case of the flow separator 230 having a more streamlined shape, the air resistance coefficient value varies depending on whether the flow boundary layer is a laminar boundary layer or a turbulent boundary layer.

That is, even when the laminar boundary layer is formed, it generally has a smaller value than the above values, and when the turbulent boundary layer is formed, the air resistance coefficient is much smaller than this.

Of course, by forming a plurality of small protrusions or holes on the surface of the plate-shaped flow separator shown in the first embodiment of the present invention described above, the air resistance coefficient may be further lowered by inducing the formation of a turbulent boundary layer. have.

On the other hand, Figures 10 and 11 attached is a structure according to a fourth embodiment of the present invention.

As described above, according to the fourth embodiment of the present invention, the flow of the cold air is increased through the structural improvement of the forming portion of each of the cold air outlet holes 51, 61, and 82 where cold air is discharged from each of the cold air ducts 50, 60. It is proposed to be done separately.

That is, as shown, the expansion portion 310 having a plurality of cold air discharge holes (311, 312, 313, 314) is formed in the portion where the cold air is discharged from each of the cold air ducts (50, 60), each of the inside of the expansion pipe (310) Adjacent portions of the cold air outlet holes 311, 312, 313, 314 are provided with plate-type flow separators 241, 242, 243, and 244, respectively.

At this time, each of the cold air outlet holes (311, 312, 313, 314) is formed to be alternating in the opening size, and each of the flow separation parts (241,242, 243, 244) also have the same size as the size of each corresponding cold air outlet (311, 312, 313, 314) Form.

In addition, a pair is fixed to the circumferential side of the portion formed with each of the cold air outlet holes (311, 312, 313, 314) protruding to the front side (side toward the cold air outlet hole) on the circumferential surface of each flow separation unit (241,242, 243, 244) Of the supporting portions 241a, 242a, 243a, and 244a, respectively.

At this time, the support parts 241a, 242a, 243a and 244a of the respective flow separation parts 241, 242, 243 and 244 may have two sides in different directions from those of the support parts 241a, 242a, 243a and 244a of the adjacent other flow separation parts 241, 242, 243 and 244a. It is installed to support it.

For example, the cold air outflow hole 311 is installed so that the direction in which the cold air flows to the cold air outlet hole 311 through the up and down direction of the flow separation unit 241 (a pair of support portion 241a is If installed on both sides of the flow separation unit 241) the outflow direction of the cold air passing through the cold air outlet hole 312 of the side to the cold air outlet hole 312 through the left and right direction of the flow separation unit 242 It is installed to flow (a pair of support 242a is installed on the upper and lower surfaces of the flow separator 242).

The above configuration is to increase the turbulence of the flow to make the vibration of the cold air larger than the structure of the other embodiments described above.

Therefore, the cold air flowing into the refrigerator through each cold air outlet hole (311, 312, 313, 314) of the expansion portion 310 can be spread in a wider direction.

As described above, the structure for the cold air flow of the refrigerator according to the present invention increases the spread of the cold air flow because the flow discharged into the refrigerator while moving through the cold air outlet hole swings up and down or left and right. It has an effect that can solve the problem that the cold air is intensively discharged to the site.

1 is a front view showing an internal state of a conventional conventional refrigerator

Figure 2 is a front view showing a structure for the cold air flow of a conventional conventional refrigerator

Figure 3 is a side cross-sectional view showing a structure for the cold air flow of a conventional conventional refrigerator

4 is a front view showing a structure for the cold air flow of the refrigerator according to the first embodiment of the present invention

Figure 5 is a side cross-sectional view showing a structure for the cold air flow of the refrigerator according to the first embodiment of the present invention

6 is an enlarged cross-sectional view of main parts for explaining a flow separation unit according to a first embodiment of the present invention;

7 is an enlarged cross-sectional view of main parts for explaining a flow separation unit according to a second embodiment of the present invention;

8 is an enlarged cross-sectional view illustrating main parts of a flow separation part according to a third exemplary embodiment of the present invention;

9A to 9C are enlarged cross-sectional views showing main parts of an embodiment of various shapes of a flow separator;

10 is a perspective view of main parts for explaining a flow separation unit according to a fourth embodiment of the present invention;

11 is an enlarged cross-sectional view illustrating main parts for explaining a flow separation unit according to a fourth exemplary embodiment of the present invention;

Explanation of symbols for main parts of the drawings

50,60. Cold Duct

51,61,82,311,312,313,314. Cold Airflow

200,210,220,230,241,242,243,244. Flow separator

241a, 242a, 243a, 244a. Support

300,310. Expansion

Claims (17)

A cold air duct for a freezer compartment and a cold air duct for a cold compartment that receives at least one cold air outlet and receives cold air from a space provided with an evaporator constituting a freezing cycle and supplies it to a freezing compartment and a refrigerating compartment; And, And a flow separation unit provided at a portion where at least one cold air outlet hole of each of the cold air ducts is formed to separate the flow of the discharged cold air into at least two or more flows. The method of claim 1, The flow separation unit Cold air flow structure of the refrigerator, characterized in that installed in a direction perpendicular to the flow direction of the cold air to block the discharged cold air. The method of claim 2, The flow separation unit Cold air flow structure of the refrigerator, characterized in that the thickness is formed in the shape of a flat plate flat. The method of claim 2, The flow separation unit The cold air flow structure of the refrigerator, characterized in that the convex rounded shape in a direction opposite to the flow direction of the cold air toward the center side. The method of claim 2, The flow separation unit The cold air flow structure of the refrigerator, characterized in that it is formed convexly curved in a direction opposite to the flow direction of the cold air toward the center side. The method of claim 2, The flow separation unit The cold air flow structure of the refrigerator, characterized in that it is formed in an elliptical shape convexly rounded in the same direction as the flow direction of the cold air and the direction opposite to the flow direction of the cold air toward the center side. The method of claim 1, The distance between the flow separator and the cold air outlet space of each cold duct is Cold air flow structure of the refrigerator, characterized in that smaller than the opening width of the cold air outlet is set. The method of claim 7, wherein The distance between the flow separator and the cold air outlet space of each cold duct is The cold air flow structure of the refrigerator, characterized in that it is formed to approximately 0.5 times the opening width of the cold air outlet hole. The method of claim 1, The width of the flow separator is Cold air flow structure of the refrigerator, characterized in that formed so as to have the same width as the cold air outlet hole of each cold duct. The method of claim 1, The cold air outlet hole of each cold air duct formed The cold air flow structure of the refrigerator, characterized in that the expansion unit is formed integrally to be expanded compared to the other parts of each cold air duct. The method of claim 10, The width of the expansion pipe Cold air flow structure of the refrigerator, characterized in that formed to form about 2 to 2.5 times the width of the corresponding cold air duct. The method of claim 10, The length of the expansion pipe Cold air flow structure of the refrigerator, characterized in that formed to form about 1 to 1.2 times the width of the corresponding cold air duct. The method of claim 10, Each part of the expansion pipe connected to each cold air duct is The cold air flow structure of the refrigerator, characterized in that the inclined so as to be gradually expanded toward the portion of the expansion portion is formed cold air outflow hole from the connection portion. The method of claim 13, The inclined portion of the expansion pipe portion is A cold air flow structure of a refrigerator, characterized in that it does not exceed approximately the portion where the flow separator is located. The method of claim 1, Two opposite sides of the flow separation unit The cold air flow structure of the refrigerator, characterized in that each pair of support portions are fixed to the circumferential side of the portion where the cold air outlet holes of the respective cold air ducts are formed to block the flow of cold air. The method of claim 15, Each support part supporting two side surfaces of each flow separation part A cold air flow structure of a refrigerator, characterized in that it is installed so as to support two sides in a different direction from the support of the other flow separation portion blocking the adjacent cold air outlet. The method of claim 16, Cold air flow structure of the refrigerator, characterized in that the adjacent cold air outlet holes are formed so that the opening width is different from each other.