KR102030846B1 - Refrigerator - Google Patents

Abstract

In order to increase the internal volume of the main body, it is possible to reduce the deformation of the main body by improving the rigidity of the lowered main body through the reinforcing structure as the insulation thickness decreases. Space utilization can be improved by being placed inside the hinge cover provided in the front, and if the fire occurs in the parts inside the electrical box, the steel inside the electrical box to prevent the fire from spreading outside the electrical box Provided is a refrigerator provided with a reinforcing plate of material.

Description

Refrigerator {REFRIGERATOR}

The present invention relates to a refrigerator having an improved structure for fixing a heat dissipation pipe to an inner phase.

In general, a refrigerator includes a main body including an inner box and an outer box, a storage chamber formed by the inner box, and a cold air supply device for supplying cold air to the storage room to keep food fresh.

The storage room temperature is maintained within a range of temperatures required for fresh food storage.

The storage compartment of such a refrigerator is provided such that its front face is opened, and the opened front face is normally closed by a door to maintain the temperature of the storage compartment.

Insulation is foamed between the inner and outer wounds to prevent cold air leakage inside the storage compartment.

Since the foaming of the insulation proceeds only at a certain temperature or more, heat is generated in the process of foaming the insulation so that the body has a temperature higher than about 20 ° C. above the room temperature in the state where the insulation is foamed between the inner and outer wounds.

After the insulation is foamed between the inner and outer wounds, as the temperature of the body decreases to room temperature, the insulation is hardened, and the body contracts heat.

The inner wound is mainly made of plastic material, and the outer wound is mainly made of steel material, and the plastic material has a heat shrinkage of about five times greater than that of the steel material, so that when the body heat shrinks, the inner wound shrinks more than the trauma. In the process of lowering the temperature to room temperature, the central portions of both sides of the main body are deformed into a convex shape toward the outside of the main body. In the state where the temperature of the main body is lowered to the normal temperature, the central parts of both sides of the main body are convex toward the outside of the main body. The heat insulator is hardened in a state where deformation is generated in the shape.

When deformation occurs in the inner and outer wounds due to the difference in the heat shrinkage of the inner and outer wounds, the deformations generated in the inner and outer wounds are partially reduced by the heat insulating material in contact with the inner and outer wounds. In order to increase the volume, if the thickness of the insulating material foamed between the inner and outer wounds is reduced, the amount of deformation in which the central portions of both sides of the main body are convex toward the outside of the main body increases as the thickness of the insulating material decreases. Even after foaming, when the temperature inside the main body decreases during operation of the refrigerator, there is a problem in that the amount of heat shrinkage of the inner phase is increased, thereby increasing the amount of deformation of the shape.

In addition, when the thickness of the heat insulating material is reduced, the heat insulating performance may be reduced, and the rigidity may be weakened, and deformation may be generated in the body by the weight of the body itself and the load of the material stored in the body.

In order to improve the insulation performance, which is reduced by the thickness of the insulation, a vacuum insulation is provided together with the insulation between the inner and outer wounds, and the vacuum insulation is disposed between the inner and outer wounds together with the insulation to compensate for the degraded insulation performance. However, it cannot compensate for the weakened stiffness.
Prior Art Korean Utility Model Publication No. 20-2000-0009607 (Invention name: Hot pipe fixing device of refrigerator, Publication Date: June 6, 2000), Korean Utility Model Publication No. 20-1998-0026844 (Name of invention: Hot pipe fixing structure of the refrigerator, published date: 1998. 08. 05.), Korean Patent Publication No. 10-1998-0027611 (Invention: Inner case of the refrigerator, published date: July 15, 1998) A fixed structure of a hot pipe is disclosed.

One aspect of the present invention provides a refrigerator capable of reducing the amount of deformation of the main body by improving the rigidity of the lowered main body through a reinforcing structure while reducing the insulation thickness to increase the internal volume of the main body.

The present invention also provides a refrigerator capable of improving space utilization by arranging an electrical box in which electrical components for controlling the operation of the refrigerator are housed inside a hinge cover provided at the front of the main body.

In addition, when a fire occurs in the parts inside the electronic box to provide a refrigerator provided with a steel reinforcement plate inside the electronic box to prevent the fire from spreading outside the electronic box.

In addition, a refrigerator having an improved structure for fixing a heat dissipation pipe to an inner phase is provided.

A refrigerator according to an embodiment of the present invention includes an inner wound in which a storage compartment is formed therein, a main body including an outer wound coupled to an outer side of the inner wound to form an outer appearance, and dew that is fixed to the front edge of the inner wound to be generated. Heat dissipation pipe to prevent condensation, the seating portion is provided on the front edge of the inner box so that the heat dissipation pipe is seated, a fixing groove provided in the seating portion and the heat dissipation pipe is fixed to the fixing groove so that the heat dissipation pipe is accommodated therein It characterized in that it comprises a clip to be fixed to the seating portion.

The seating portion may be provided at an end of the front edge of the inner shell to be provided at a position adjacent to the trauma when the inner wound and the trauma are coupled.

The seating part may be provided at an end of the front edge of the inner box, and the heat dissipation pipe seated on the seating part may be disposed at a position spaced apart from the inside of the storage compartment.

The heat dissipation pipe may be disposed at a position spaced apart from the inside of the storage compartment such that high temperature heat transmitted by the high temperature refrigerant flowing into the heat dissipation pipe may be reduced.

Since the heat dissipation pipe is disposed at a position adjacent to the trauma, the temperature difference between the inside and the outside of the trauma is reduced by the high temperature heat caused by the high temperature refrigerant flowing into the heat dissipation pipe, resulting in dew condensation generated on the outer surface of the trauma. This can be prevented.

The fixing groove may include a first fixing groove and a second fixing groove to which both ends of the club are fitted and fixed.

The clip may include a first fixing part inserted into and fixed to the first fixing groove, and a second fixing part inserted into and fixed to the second fixing groove.

In addition, the refrigerator according to an embodiment of the present invention is fixed to the front edge of the inner body of the main body including an inner wound in which a storage compartment is formed therein, and an outer wound coupled to an outer side of the inner wound to form an exterior, and the trauma is generated. And a clip for fixing the heat dissipation pipe to prevent dew condensation and the heat dissipation pipe fixed to the front edge of the inner phase.

The front edge of the inner phase may be provided with a plurality of seating portion on which the heat dissipation pipe is mounted.

At least one of the seating parts may be provided with a fixing groove for fixing the clip.

The fixing groove may include a first fixing groove and a second fixing groove to which both ends of the club are fitted and fixed.

The clip may include a first fixing part inserted into and fixed to the first fixing groove, and a second fixing part inserted into and fixed to the second fixing groove.

According to embodiments of the present invention, the rigidity can be maintained even if the insulation thickness is reduced through the reinforcing structure, thereby reducing the occurrence of deformation of the main body.

In addition, the electrical equipment can be arranged inside the hinge cover to improve the space utilization, it is possible to prevent the fire generated inside the electrical equipment box from spreading outside the electrical equipment box.

In addition, the heat dissipation pipe can be disposed in a position adjacent to the trauma to prevent dew condensation generated on the outer surface of the trauma, it can be easily fixed to the inner heat dissipation pipe.

1 is a perspective view of a refrigerator according to one embodiment of the present invention;
Figure 2 is a cross-sectional view showing the side of the refrigerator according to an embodiment of the present invention.
3 is a sectional view showing the front of a refrigerator according to one embodiment of the present invention;
4 is a view showing a state in which the reinforcing member is attached to the inner phase according to an embodiment of the present invention.
5 is a cross-sectional view showing a state in which the first reinforcing member is attached to the inner in accordance with an embodiment of the present invention.
Figure 6 is a view showing a state in which the reinforcing member is attached to the trauma in accordance with an embodiment of the present invention.
Figure 7 is a view showing a state in which the reinforcing member is attached in the longitudinal direction on the inner side in accordance with an embodiment of the present invention.
8 is a view showing a state in which the reinforcing frame is coupled to the main body according to an embodiment of the present invention.
9 is a perspective view of the reinforcing frame according to an embodiment of the present invention.
10 is an exploded perspective view of an electrical equipment box provided in the refrigerator according to one embodiment of the present invention;
FIG. 11 is an exploded perspective view illustrating a bottom view of a battlefield box according to an embodiment of the present invention. FIG.
12 is a perspective view of a battlefield box according to an embodiment of the present invention.
Figure 13 is a cross-sectional view showing a state in which the electric box is provided in the main body according to an embodiment of the present invention.
14 is a view showing a wire connected to the electric box according to an embodiment of the present invention.
15 is a view schematically showing a state in which the heat dissipation pipe is disposed in the main body according to an embodiment of the present invention.
16 is a diagram illustrating an inner wound and an outer wound on which a heat dissipation pipe is disposed according to an embodiment of the present invention.
17 is a view showing a state in which the heat dissipation pipe is fixed to the inner phase according to an embodiment of the present invention.
18 is a view showing a state in which a seating portion for mounting a heat dissipation pipe and a fixing groove for fixing the heat dissipation pipe are provided on an inner side according to an embodiment of the present invention.
19 is a view showing a state in which the heat dissipation pipe is disposed in the main body according to an embodiment of the present invention.
20 is a view showing a state in which a storage unit is provided in a storage compartment according to an embodiment of the present invention.
21 is a view illustrating a sliding shelf coupled to a storage compartment according to an embodiment of the present invention.
FIG. 22 is a view illustrating a sliding shelf coupled to a storage compartment in accordance with an embodiment of the present invention. FIG.
23 is a view showing a state in which the first storage box is coupled to the sliding shelf according to an embodiment of the present invention.
24 is an enlarged view illustrating a portion of the cover rail of FIG. 23 coupled to the coupling unit;
25 is a view showing a sliding shelf coupled to the first storage box according to an embodiment of the present invention.
FIG. 26 is a view illustrating a sliding shelf according to an embodiment of the present invention as viewed from the bottom. FIG.
FIG. 27 is a view illustrating a sliding part drawn out from the sliding shelf of FIG. 26;
28 is an exploded perspective view of a self-closing device according to an embodiment of the present invention.
29 illustrates a self closing device according to an embodiment of the present invention.
30 is a view showing a part of the self-closing device according to an embodiment of the present invention as viewed from the bottom.
31 is a view illustrating a state in which a first storage box and a second storage box are separated according to an embodiment of the present invention.
32 is a view showing a side view of the storage unit according to an embodiment of the present invention.
FIG. 33 is a view illustrating a state in which a second storage box is moved in FIG. 32.
34 is a view illustrating a state in which a second storage box is disposed inside the first storage box according to an embodiment of the present invention.
35 is a view showing a shelf unit according to an embodiment of the present invention.
36 is a view showing a state in which the first shelf is separated from the support in FIG.
37 is a view showing a state in which the horizontal holding unit is coupled to the bracket according to an embodiment of the present invention.
38 is a view showing a state in which the horizontal holding unit is coupled to the shelf according to an embodiment of the present invention.
39 is a view showing a state in which the fixing projection is inserted into the fixing groove according to an embodiment of the present invention.
40 is a view showing the inside of the upper reservoir according to an embodiment of the present invention.
41 is an exploded perspective view of a first cold air duct according to an embodiment of the present invention.
42 is a view illustrating a state in which a first cold air duct is disposed in a refrigerator according to an embodiment of the present invention.
43 is a view showing a state in which a straight guide member is disposed in the refrigerator according to one embodiment of the present invention;
FIG. 44 is a view illustrating a state in which the straight guide member of FIG. 43 is coupled to an insulator inlet provided in a machine room cover.
45 is a view showing a guide member coupled to the insulator injection hole provided in the machine room cover according to another embodiment of FIG. 44.
46 is a view illustrating a state in which a Y-type guide member is disposed in a refrigerator according to one embodiment of the present invention.
47 is a view showing a state in which the Y-shaped guide member of Figure 46 is coupled to the insulator inlet provided in the machine room cover.
48 is a view illustrating a state in which a guide member according to another embodiment of FIG. 47 is coupled to an insulator injection hole provided in a machine room cover.
49 is a view showing a state in which the refrigerant pipe and the drain pipe are disposed on the side of the body according to an embodiment of the present invention.

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

As shown in FIGS. 1 to 3, the refrigerator opens and closes a main body 10, a plurality of storage chambers 20 provided to open the front surface of the main body 10, and an open front surface of the storage chamber 20. The door 30 is rotatably coupled to the main body 10, and the hinge unit 40 allows the door 30 to be rotatably coupled to the main body 10.

The main body 10 includes an inner wound 11 forming the storage compartment 20 and an outer wound 13 forming the outer appearance, and includes a cold air supply device for supplying cold air to the storage compartment 20.

The cold air supply device may include a compressor (C), a condenser (not shown), an expansion valve (not shown), an evaporator (E), a blowing fan (F), a cold air duct (D), and the like. The heat insulating material 15 is foamed between the inner case 11 and the outer case 13 of the main body 10 so as to prevent cold air from leaking out of the storage compartment 20.

The compressor C, the condenser, the expansion valve, and the evaporator E may be connected by the refrigerant pipe P, and the refrigerant may be guided through the refrigerant pipe P.

The rear of the main body 10 is provided with a compressor (C) for compressing the refrigerant and condensing the compressed refrigerant and a machine room (28) in which the condenser is installed.

The evaporator E includes a first evaporator E1 for supplying cold air to the upper storage chamber 21 to be described later, and a second evaporator E2 for supplying cold air to the lower storage chamber 23, and a first evaporator E1. The cold air generated by) is supplied to the upper storage chamber 21 through the first blowing fan F1, and the cold air generated by the second evaporator E2 is supplied to the lower storage chamber 23 through the second blowing fan F2. Can be supplied.

The cold air duct D is provided at the rear side of the upper storage compartment 21 so that the cold air generated by the first evaporator E1 is supplied to the upper storage compartment 21 through the first blowing fan F1. The first cold air duct 700 to form a and the cold air generated by the second evaporator (E2) provided on the rear of the lower storage chamber 23 is supplied to the lower storage chamber 23 through the second blowing fan (F2). And a second cold air duct 760 forming a second flow path 763.

The first cold air duct 700 is provided with a first cold air outlet 711 to supply the cold air generated in the first evaporator E1 to the upper storage chamber 21 through the first cold air outlet 711, the second cold air duct A second cold air discharge outlet 761 is provided at 760 to supply cold air generated by the second evaporator E2 to the lower storage chamber 23 through the second cold air discharge outlet 761.

The storage compartment 20 is divided into a plurality of partitions by the partition 17. The partition 17 divides the storage compartment 20 into an upper storage compartment 21 and a lower storage compartment 23, and a lower storage compartment. And a second partition 17b that divides 23 into the left storage compartment 25 and the right storage compartment 26.

The upper storage compartment 21 of the upper storage compartment 21 and the lower storage compartment 23 divided by the first partition 17a may be used as a refrigerating compartment, and the lower storage compartment 23 is the left storage compartment by the second partition 17b. The left compartment 25 may be used as a freezer compartment and the right compartment 26 may be used as both a freezer compartment and a refrigerating compartment.

The division of the storage compartment 20 as described above is an example, and each of the storage compartments 21, 25, and 26 may be used differently from the configuration described above.

A plurality of shelf units 600 may be provided in the storage compartment 20 to divide the storage compartment 20 into a plurality of compartments, and a plurality of storage containers 27 may be provided to store food and the like.

The open front of the storage compartment 20 is opened and closed by a door 30 which is rotatably coupled to the main body 10, and a plurality of door guards 31 are provided on the rear of the door 30 to accommodate food and the like. Can be.

The hinge unit 40 allows the door 30 to be rotatably coupled to the main body 10, the upper hinge 41 coupled to the upper portion of the main body 10, and the intermediate hinge coupled to the first partition 17a. 43 and a lower hinge (not shown) coupled to the lower portion of the main body 10.

As shown in Figures 1 to 3, the heat insulating material 15 that is foamed between the inner wound 11 and the outer wound 13 of the main body 10 is mainly used urethane (Urethane), the foam of the heat insulating material 15 Only proceeds above a certain temperature.

Since the foaming of the heat insulating material 15 proceeds only at a predetermined temperature or more, heat is generated in the process of foaming the heat insulating material 15, so that the heat insulating material 15 is foamed between the inner wound 11 and the outer wound 13 and the main body ( 10) has a temperature of about 20 ° C. or higher than room temperature.

After the insulating material 15 is foamed between the inner wound 11 and the outer wound 13, the temperature of the main body 10 decreases to room temperature, and the thermal insulating material 15 is hardened, and the main body 10 undergoes heat shrink. .

The inner wound 11 is mainly made of a plastic material, the outer wound 13 is mainly made of a steel material, and since the heat shrinkage of the plastic material is about five times greater than that of the steel material, when the main body 10 is heat shrinked, As the inner wound 11 contracts larger than the outer wound 13 so that the temperature of the main body 10 decreases to room temperature, the central portions of both sides of the main body 10 are deformed into a convex shape toward the outside of the main body 10. In the state where the temperature of the main body 10 is lowered to room temperature, the heat insulating material 15 is hardened in a state where the central portions of both sides of the main body 10 are convex toward the outside of the main body 10.

In addition, in order to increase the internal volume of the main body 10 while having the same outer size, the thickness of the heat insulating material 15 foamed between the inner wound 11 and the outer wound 13 should be reduced, and the thickness of the heat insulating material 15 is reduced. In order to compensate for the deterioration of heat insulation performance due to the vacuum insulation material 19 is provided between the inner wound (11) and the outer wound (13).

The vacuum insulating material 19 is also disposed inside the heat insulating material 15 that is foamed between the inner wound 11 and the outer wound 13 of the main body 10, but the heat insulating material 15 and the partition 17 that are foamed inside the door 30. Insulation material 15 is foamed in the inside, it may be arranged in the heat insulating material 15 is foamed between the machine room cover 29 and the inner box (11).

When deformation occurs in the inner wound 11 and the outer wound 13 due to the difference in heat shrinkage between the inner wound 11 and the outer wound 13, the deformations generated in the inner wound 11 and the outer wound 13 are caused by the inner wound 11 and the outer wound 13. The heat insulating material 15 in contact with the trauma 13 is reduced in part. When the thickness of the heat insulating material 15 is reduced, the thickness of the heat insulating material 15 is reduced, so that the central portions of both sides of the main body 10 are formed in the main body ( The deformation amount deformed into a convex shape toward the outside of the 10) increases, and even after the insulation 15 is foamed, the heat shrinkage amount of the inner phase 11 is increased as the temperature inside the main body 10 decreases when the refrigerator operates. The amount of deformation may increase.

Therefore, after the heat insulating material 15 is foamed between the inner wound 11 and the outer wound 13, the temperature of the main body 10 decreases to room temperature, which is caused by the difference in the heat shrinkage between the inner wound 11 and the outer wound 13. As shown in FIGS. 4 to 5 to prevent deformation of the shape, the reinforcing member 100 is provided on both side surfaces of the main body 10.

The reinforcing member 100 may be provided of a steel material, and is disposed inside the heat insulating material 15 between the inner wound 11 and the outer wound 13 at both sides of the main body 10 so that the inner wound 11 and the outer wound have their own rigidity. The deformation of the shape caused by the difference in heat shrinkage amount of (13) is prevented.

The reinforcing member 100 may be disposed in the horizontal direction or the vertical direction on both sides of the main body 10 according to the flowing direction of the heat insulating material 15 foamed between the inner wound 11 and the outer wound 13.

When the heat insulating material 15 is foamed between the inner wound 11 and the outer wound 13 and flows from the rear side of the main body 10 toward the front side, the reinforcing member 100 is disposed on both sides of the main body 10 in the horizontal direction. do.

When the reinforcing member 100 is disposed in both sides of the main body 10 in the horizontal direction, the reinforcing member 100 divides the storage compartment 20 into an upper storage compartment 21 and a lower storage compartment 23. The first reinforcing member 110 disposed on the upper side of the first partition 17a and the second reinforcing member 120 disposed on the lower side of the first partition 17a may be included based on 17a).

As shown in FIG. 4, the first reinforcing member 110 and the second reinforcing member 120 may be attached to the inner wound 11 between the inner wound 11 and the outer wound 13, as shown in FIG. 6. As may be attached to the trauma 13.

The first reinforcing member 110 and the second reinforcing member 120 are attached to either the inner wound 11 or the outer wound 13 as long as the first reinforcing member 110 and the second reinforcing member 120 are positioned inside the heat insulating material 15 between the inner wound 11 and the outer wound 13. It does not matter.

The first reinforcing member 110 disposed on the upper side of the main body 10 may have a length shorter than the front and rear lengths of both sides of the main body 10 and may have a thickness T1 of about 0.5 mm.

The first reinforcing member 110 has a height H1 as high as possible to increase the cross-sectional coefficient in the direction in which the shape of the inner wound 11 and the outer wound 13 is deformed between the inner wound 11 and the outer wound 13. It is preferable to provide.

The first reinforcing member 110 may be provided in a concave-convex shape that may have a maximum height (H) without disturbing the flow of the heat insulating material 15 that is foamed between the inner wound (11) and the outer wound (13).

The first reinforcing member 110 may be attached to the inner wound 11 or the outer wound 13 by an adhesive means such as a double-sided tape, and although not shown in the drawing, the first reinforcing member 110 may be attached to the inner wound 11 or the outer wound 13. The first reinforcing member 110 may be provided with a fixing means for fixing the first reinforcing member 110 to the inner box 11 or the outer box 13 to prevent flow when the heat insulating material 15 is foamed.

Like the first reinforcing member 110, the second reinforcing member 120 disposed on the lower side of the main body 10 has a length shorter than the front and rear lengths of both sides of the main body 10, and has a thickness T2 of approximately 0.5 mm. It can be provided to have, and to have the highest height (H2) between the inner wound (11) and the outer wound (13) in order to increase the cross-sectional coefficient in the direction in which the shape of the inner wound (11) and the outer wound (13) is deformed Can be prepared.

Similarly to the first reinforcing member 110, the second reinforcing member 120 is not shown in the drawing, but the second reinforcing member 120 attached to the inner or inner wounds 11 or the outer wounds 13 is foamed with the heat insulating material 15. When it is possible to provide a fixing means for fixing the second reinforcing member 120 to the inner box 11 or the outer box 13 to prevent flow.

As shown in FIG. 7, when the heat insulating material 15 is foamed between the inner wound 11 and the outer wound 13 and flows in a direction from the upper portion to the lower portion of the main body 10, the reinforcing member 130 may move to the main body 10. Are arranged in the longitudinal direction on both sides of the.

When the reinforcing member 130 is disposed in both sides of the main body 10 in the longitudinal direction, the reinforcing member 130 may have a shorter length than the vertical length of both sides of the main body 10, and may have a thickness of about 0.5 mm.

The reinforcing member 130 disposed in both sides of the main body 10 in the longitudinal direction may have the same shape as the first reinforcing member 110 and may be provided in a form of a length longer than that of the first reinforcing member 110. .

In addition, the reinforcing member 130 is attached to the inner wound 11 between the inner wound 11 and the outer wound 13, as shown in FIG. 7, similar to the first and second reinforcing members 110 and 120. Although not shown in the drawings, it may be attached to the trauma 13.

As described above, the reinforcing members 100 and 130 are provided between the inner wounds 11 and the outer wounds 13 on both sides of the main body 10 so that the rigidity is reinforced, so that the difference in the heat shrinkage between the inner wounds 11 and the outer wounds 13 is increased. The deformation amount of the main body 10 can be reduced.

As shown in FIGS. 1 to 3, the heat insulating material 15 that is foamed between the inner wound 11 and the outer wound 13 in order to increase the inner volume of the main body 10 while having the same outer size. The thickness of the heat insulating material 15 should be reduced, but if the thickness of the heat insulating material 15 is reduced, the heat insulating performance may be degraded, and the rigidity may be weakened, and thus the body may be affected by the weight of the body 10 itself and the load of the material stored in the body 10. Deformation may occur in 10).

The vacuum insulation panel (VIP) 19 may be provided together with the insulation 15 between the inner wound 11 and the outer wound 13 so as to reduce the thickness of the insulation 15 to reduce the insulation performance. have.

Vacuum insulator (19) has a thermal insulation performance of about 8 times or more than the general thermal insulator (15), it is a product vacuumed inside to maximize the thermal insulation performance.

The vacuum insulator 19 is disposed between the inner wound 11 and the outer wound 13 together with the heat insulating material 15 to compensate for the reduced heat insulating performance, but cannot compensate for the weakened rigidity.

8 to 9, the reinforcement frame 200 is provided on the front surface of the main body 10 to compensate for the weakened rigidity of the main body 10.

The reinforcement frame 200 is disposed on the front surface of the inner box 11 to supplement the rigidity of the main body 10, and the upper reinforcing frame 210 coupled to the upper front of the inner box 11, and the front of the inner box 11. Intermediate reinforcement frame 220 is coupled to the central portion to which the first partition 17a is coupled, the lower reinforcement frame 230 is coupled to the front lower portion of the inner box 11, and is coupled to both sides of the front of the inner box 11 It includes a first side reinforcement frame 240 and the second side reinforcement frame 250.

The first side reinforcement frame 240 is disposed on both sides of the upper side of the front of the inner box 11, the top is arranged to overlap a part with the upper reinforcement frame 210, the bottom is the middle reinforcement frame 220 and the lower part from the top It is provided to extend between the reinforcement frame 230.

The second side reinforcement frame 250 is disposed on both side lower sides of the front of the inner box 11, the bottom is coupled to the lower reinforcement frame 230 and the top is a predetermined distance from the bottom of the first side reinforcement frame 240 from the bottom It is provided to extend to a spaced position.

As shown in Figures 1 to 3, the front of the upper portion of the main body 10 is provided with an electrical equipment box 300 containing the electrical components for controlling the operation of the refrigerator.

As shown in FIGS. 10 to 14, the electrical equipment box 300 includes a base 310 installed to cover the electrical equipment box mounting hole 13a provided in front of the upper portion of the main body 10, and the base 310. A cover 320 covering the upper portion of the base 310 to be provided in the accommodation space (S), a printed circuit board 330 provided in the accommodation space (S) and mounted with electronic components 331, and a printed circuit It includes a printed circuit board mounting portion 340 on which the substrate 330 is mounted, and a reinforcing plate 350 provided between the printed circuit board mounting portion 340 and the cover 320.

The base 310 is a base portion 311 coupled to the front of the upper portion of the main body 10, and when the base portion 311 is coupled to the front of the upper portion of the main body 10 is accommodated in the electric box installation hole 13a Groove 317.

The base 311 forms an edge of the receiving groove 317 having a rectangular shape, and a plurality of fixing hooks 313 are provided at the front edge and the rear edge, respectively, and the printed circuit board 330 is disposed at both rear sides thereof. ) Is provided with a wire through hole 315 for connecting the wire 333 connected to the inside of the main body 10.

The fixed hook 313 includes a plurality of first fixing hooks 313a provided at the front edge of the receiving groove 317 and a plurality of second fixing hooks 313b provided at the rear edge of the receiving groove 317. It includes.

The first fixing hook 313a is fitted and fixed to the upper reinforcing frame 210 coupled to the upper front of the inner box 11, and the second fixing hook 313b is fitted to the rear edge of the electric box installation hole 13a. do.

Since the first fixing hook 313a and the second fixing hook 313b provided on the base 311 are fixed to the rear edges of the upper reinforcing frame 210 and the electric box mounting hole 13a, respectively, the base 310 Base 310 acts as a trauma when it is coupled to the front of the upper body 10, the base 310 by the foam pressure when the heat insulating material 15 is foamed between the inner wound (11) and the outer wound (13) To keep the flow fixed.

Since the receiving groove 317 is accommodated in the electric box mounting hole 13a provided in the front of the upper portion of the main body 10, the receiving groove 317 has a shape recessed in the upper portion of the main body 10 based on the upper portion of the main body 10.

Since the accommodating groove 317 is provided in a shape recessed in the upper portion of the main body 10, the height of the accommodating space S provided between the base 310 and the cover 320 is increased while the upper part of the main body 10 is apparent. The height of the electrical equipment box 300 is provided in the front can be made low.

The cover 320 is coupled to the upper portion of the base 310 so that the accommodation space S is provided between the base 310 and the cover 320, and the door 30 is rotatably coupled to the main body 10. The hinge cover part 321 covers an upper portion of the upper hinge 41 coupled to the upper portion of the main body 10.

The plurality of printed circuit boards 330 are provided in a receiving space S provided between the base 310 and the cover 320, and a plurality of electronic components 331 are disposed on the lower surface of each printed circuit board 330. ) Is implemented.

A plurality of printed circuit boards 330 are mounted on the printed circuit board mounting portion 340 on an upper surface on which the electronic components 331 are not mounted, and the printed circuit board mounting portion 340 is coupled to the cover 320.

Since the printed circuit board mounting portion 340 on which the plurality of printed circuit boards 330 is mounted is coupled to the cover 320, the plurality of printed circuit boards 330 are formed in the accommodation space S with the upper storage chamber 21. It is located in a distant location.

Since the plurality of printed circuit boards 330 are located farthest from the upper storage compartment 21 in the accommodation space S, the plurality of printed circuit boards 330 may be generated from the electronic components 331 mounted on the plurality of printed circuit boards 330. The transfer of heat into the upper reservoir 21 can be prevented as much as possible.

The connector coupling part 341 is provided at both sides of the printed circuit board mounting part 340, and the wire connector 335 to which the wire 333 connected to the printed circuit board 330 is fixed is coupled to the connector coupling part 341. do.

Accordingly, the wire 333 connected to the printed circuit board 330 is agglomerated and fixed by the wire connector 335 coupled to the connector coupling part 341, and the wire 333 agglomerated by the wire connector 335 is formed of a base ( It is connected to the inside of the main body 10 through the wire through hole 315 provided in 310.

Accordingly, the wire 333 connected to the printed circuit board 330 passes through the wire through hole 315 provided in the base 310 through both side surfaces of the printed circuit board mounting part 340, and passes through the wire through hole 315. The penetrated wire 333 may be connected to the inside of the main body 10 through the hinge hole 41a of the upper hinge 41.

A reinforcement plate 350 made of steel is provided between the printed circuit board mounting portion 340 on which the plurality of printed circuit boards 330 is mounted and the cover 320.

The reinforcement plate 350 protects the electronic components 331 by reducing the shock transmitted to the plurality of printed circuit boards 330 accommodated in the accommodation space S when an impact is applied to the upper portion of the electronic box 300. .

In addition, the reinforcement plate 350 prevents the fire from spreading outside the electrical box 300 when a fire occurs in the electronic components 331 mounted on the plurality of printed circuit boards 330, so that a fire accident may occur. Can be reduced.

As illustrated in FIGS. 15 to 19, a heat dissipation pipe 400 is provided at the front edge of the inner wound 11 of the main body 10 to prevent dew formation occurring on the outer wound 13.

When the refrigerator is operated, cold air inside the storage compartment 20 flows into the outer wound 13 forming the outer appearance of the main body 10, and thus the outer surface of the outer wound 13 is caused by a temperature difference between the inside and the outer wound 13. Dew condensation may occur.

In order to prevent dew condensation generated on the outer surface of the outer wound 13, the heat dissipation pipe 400 through which a high temperature refrigerant flows is fixed to the front edge of the inner wound 11.

The front edge of the inner box 11 is provided with a plurality of seating portion 410 on which the heat dissipation pipe 400 is seated.

The seating portion 410 provided at the front edge of the inner wound 11 may be provided at a position as close as possible to the outer wound 13 when the inner wound 11 and the outer wound 13 are combined.

Since the seating portion 410 is provided at a position as close as possible to the trauma 13, the heat dissipation pipe 400 seated at the seating portion 410 is disposed at a position spaced apart from the inside of the storage compartment 20 as much as possible. ) May be placed as close as possible.

Since the heat dissipation pipe 400 is disposed at a position as far as possible from the inside of the storage compartment 20, it is possible to reduce the transfer of high temperature heat by the high temperature refrigerant flowing into the heat dissipation pipe 400 into the storage compartment 20. have.

When the high temperature heat is transferred into the storage compartment 20, the temperature inside the storage compartment 20 is increased by the high temperature heat, so that energy is consumed to lower the temperature inside the storage compartment 20.

Since the heat dissipation pipe 400 is spaced apart from the storage compartment 20 as much as possible to reduce the transfer of high-temperature heat into the storage compartment 20, the rising width of the temperature inside the storage compartment 20 is reduced, so that the temperature inside the storage compartment 20 is reduced. The consumption of energy to lower the can be reduced.

In addition, since the heat dissipation pipe 400 is disposed at the position as close as possible to the trauma 13, the heat of the high temperature due to the high temperature refrigerant flowing into the heat dissipation pipe 400 is well transmitted to the trauma 13, so that the storage chamber 20 is provided. Even if cold air is introduced into the trauma 13, a temperature difference between the outside of the trauma 13 and the inside is reduced, thereby preventing dew condensation generated on the outer surface of the trauma 13.

The heat dissipation pipe 400 seated on the seating part 410 may be fixed to the seating part 410 by a plurality of clips 430, and a plurality of seating parts 410 of some seating parts 410 may be fixed. Fixing grooves 420 to which the two clips 430 are fixed are provided.

The fixing groove 420 includes a first fixing groove 421 and a second fixing groove 423 to which both ends of the clip 430 are inserted and fixed, respectively, and the clip 430 is inserted into the first fixing groove 421. And a second fixing part 433 which is inserted into and fixed to the first fixing part 431 and the second fixing groove 423 to be fixed.

The clip 430 is fixed to the fixing groove 420 to accommodate the heat dissipation pipe 400 therein so that the heat dissipation pipe 400 is fixed to the seating portion 410.

Since the heat dissipation pipe 400 is fixed to the seat 410 by the clip 430, the heat dissipation pipe 400 can be easily fixed to the front edge of the inner box 11.

As illustrated in FIGS. 1 and 2, a storage unit 500 sliding in the front-rear direction is provided in the storage chamber 20.

The storage unit 500 may be provided in the left storage compartment 25 or the right storage compartment 27 of the lower storage compartment 23, and will be described as a storage unit 500 provided in the right storage compartment 26 for convenience.

20 to 27 and 31, the storage unit 500 is supported on both side walls of the right storage chamber 26, the first storage box 510 and the sliding movement in the front and rear direction, and the first storage box 510 includes a second storage box 520 that is slidably moved in the front-rear direction and a sliding shelf 530 that draws the first storage box 510 into the right storage compartment 26 in a sliding manner. .

The sliding shelf 530 is coupled to the lower portion of the first storage box 510 to allow the first storage box 510 to be pulled into and out of the right storage compartment 26.

Coupling portions 26a for coupling the cover rails 550 may be provided at both sidewalls of the right storage compartment 26, and the coupling part 26a may be integrally provided at both sidewalls of the right storage compartment 26.

Coupling portion 26a is provided so that cover rail 550 can be fitted by a sliding method.

Looking at the process of the sliding shelf 530 is installed, first slide the cover rail 550 of the sliding shelf 530 to the engaging portion (26a) by the sliding method, the fastening member (B) cover rail 550 The cover rail 550 is coupled to the coupling part 26a by being inserted into the fastening hole 551 provided in the coupling hole 551.

When the cover rail 550 is coupled to the coupling part 26a, the slide unit 540 is pulled out of the right storage compartment 26, and then the coupling protrusion 541a provided in the slide unit 540 is the first storage box 510. The first storage box 510 is coupled to the slide unit 540 to be inserted into the coupling groove 511.

When the first storage box 510 is coupled to the slide unit 540, since the slide unit 540 is guided along the cover rail 550 by a sliding method, the first storage box 510 is moved to the right storage compartment 26. Can be pulled in and out internally.

Since the sliding shelf 530 is coupled to the lower portion of the first storage box 510, the first storage box 510 may be completely drawn out of the right storage chamber 26 to be stored in the first storage box 510. Food and the like can be easily taken out and used.

In addition, since the sliding shelf 530 has a structure that is coupled to the lower portion of the first storage box 510, the sliding shelf 530 of the sliding shelf 530 without coupling the first storage box 510 to the upper portion of the sliding shelf 530. Food may be directly stored in the upper portion, or the first storage box 510 may be coupled to the upper portion of the sliding shelf 530 to store the food in the first storage box 510.

Next, look at the configuration of the sliding shelf in detail.

20 to 27, the sliding shelf 530 includes a cover rail 550 coupled to both sidewalls of the right storage compartment 26, and a slide unit 540 slidably moved along the cover rail 550. And, the self-closing device 560 is coupled to the slide unit 540 to transmit the elastic force in the direction in which the first storage box 510 is drawn in so that the first storage box 510 can be easily closed with only a small force. Include.

The slide unit 540 includes a sliding portion 541 coupled to the lower portion of the first storage box 510 and slide rails 543 provided on both sides of the sliding portion 541 to slide along the cover rail 550. It includes.

Coupling protrusions 541a protruding in the upper direction for coupling the first storage box 510 and the sliding part 541 are provided at both upper sides of the front side of the sliding part 541, and the first storage box 510 is provided in the first storage box 510. A coupling groove 511 into which the coupling protrusion 541a is inserted is provided at a position corresponding to the coupling protrusion 541a.

As described above, the cover rail 550 is coupled to and fixed to the coupling part 26a, and guides the first storage box 510 to be pulled into and out of the right storage chamber 26 by a sliding method.

As shown in FIGS. 26 to 30, the self-closing device 560 is provided at both sides of the lower portion of the sliding part 541 to form an exterior, and is provided in the case 570 to store the first storage. An elastic unit 580 and an elastic unit 580 that accumulate an elastic force when the box 510 is drawn out and transmit an elastic force in a direction in which the first storage box 510 is inserted when the first storage box 510 is inserted. And an oil damper 590 that absorbs the shock generated when the first storage box 510 is retracted.

The elastic unit 580 includes a slider 581 linearly moving inside the case 570, a rotator 583 rotatably coupled to the slider 581, and both ends of the slider 581 and the case 570. It includes an elastic member 585 connected to.

The slider 581 includes a rotation hole 581a to which the rotation shaft 583b provided in the rotator 583 to be rotatably coupled, a first fixing groove 581b to which the elastic member 585 is fixed, and an oil damper. 590 includes a second fixing groove 581c to which it is fixed.

The slider 581 moves linearly with the rotator 583 along the guide rail 571 to be described below, and the elastic member 585 fixed to the first fixing groove 581b of the slider 581 is tensioned by the linear motion. In this way, the elastic member 585 can accumulate elastic force.

The rotator 583 has a protrusion 583a which protrudes downward from the rotator 583 so that the rotator 583 can be guided along the guide rail 571 and is accommodated in the guide rail 571, and the rotator 583. ) Includes a rotation shaft 583b for rotatably coupling the slider 581, and a locking groove 583c provided to receive and latch the locking member 553 provided on the cover rail 550.

The protrusion 583a is provided to protrude toward the guide rail 571 under the rotator 583 so as to move along the guide rail 571 so that the rotator 583 can be guided along the guide rail 571.

The rotation shaft 583b is provided above the rotator 583 so as to be rotatably coupled to the rotation hole 581a of the slider 581.

The rotator 583 is rotated about the rotation axis 583b by the rotation axis 583b, and then rotates along a linear section with the slider 581.

The locking groove 583c is provided so that the locking member 553 provided on the cover rail 550 is caught so that the rotator 583 moves together with the first storage box 510 when the first storage box 510 is pulled in and pulled out. It can be moved along the guide rail (571).

Since the locking member 553 provided on the cover rail 550 fixed to the coupling portion 26a of the right storage compartment 26 maintains a fixed state, the rotator may be inserted and removed from the first storage box 510. When the locking member 553 is caught by the locking groove 583c of the 583, the rotator 583 moves along the guide rail 571.

The elastic member 585 may be provided with a spring, and both ends thereof are fixed to the case 570 and the slider 581, respectively.

The sides fixed to the case 570 of both ends of the elastic member 585 remain fixed, and the side fixed to the slider 581 is moved together with the slider 581 when the slider 581 moves linearly. Tension is returned to its original state again to transfer the elastic force to the first storage box (510).

The case 570 is provided under the sliding part 541 to form an exterior, and the elastic unit 580 and the oil damper 590 are accommodated therein.

The guide portion 573 which is a passage through which the guide rail 571 to which the protrusion 583a of the rotator 583 is accommodated and moved and the locking member 553 to be moved together with the rotator 583 are moved inside the case 570. ), A fixing part 575 to which the elastic member 585 is fixed, a first accommodating part 577 to accommodate the elastic member 585, and a second accommodating part 579 to accommodate the oil damper 590. Is prepared.

As described above, the guide rail 571 is provided so that the protrusion 583a provided in the rotator 583 may be accommodated and moved to guide the rotator 583 and the slider 581.

The guide rail 571 is a straight line 571a for guiding the rotator 583 to linearly move in the front-rear direction, and a latch provided at one end of the straight line 571a so that the rotator 583 can be rotated and fixed. Section 571b.

The guide part 573 is provided in parallel with the straight path 571a of the guide rail 571 so as to be caught by the locking groove 583c of the rotator 583 so that the locking member 553 moving together with the rotator 583 may linearly move. Guide to help.

The oil damper 590 is filled with oil therein and is housed in the body 591 accommodated in the second accommodating part 579 of the case 570, and is accommodated in the body 591 and has one end of the slider 581. And a flow portion 593 fixed to the two fixing grooves 581c.

Since one end of the flow portion 593 is fixed to the slider 581, the flow portion 593 moves with the slider 581.

The slider 581 also moves together with the first storage box 510 in the same direction as the first storage box 510 when the first storage box 510 is pulled in and out. When the flow portion 593 is also drawn into the body portion 591, when the first storage box 510 is drawn out, the flow portion 593 is also drawn out from the inside of the body portion 591.

Since the flow portion 593 is absorbed by the oil filled in the body portion 591 in the operation of drawing out the inside portion of the body portion 591, the first storage is performed by the elastic force of the elastic unit 580. Rapid movement of the elastic unit 580 generated when the box 510 is inserted may be prevented.

Therefore, when the first storage box 510 is retracted, the shock generated as the first storage box 510 is rapidly retracted by the elastic force of the elastic unit 580 may be absorbed to reduce noise.

The body portion 591 maintains the state accommodated inside the second accommodating portion 579 of the case 570, and only the flow portion 593 is moved together with the slider 581, and the inflow and outflow into the body portion 591 is performed. The locking jaw 579a is provided in the second accommodating part 579 so as to be possible.

The locking jaw 579a is formed to form a space through which the body portion 591 can not pass but the flow portion 593 can pass through the body portion 591 when the flow portion 593 moves with the slider 581. Is caught by the locking jaw (579a) to prevent movement.

The first storage box 510 is introduced into and withdrawn from the right storage compartment 26 in a sliding manner by the sliding shelf 530.

31 to 34, the first storage box 510 includes a coupling groove 511 to which the coupling protrusion 541a of the sliding shelf 530 is fitted, and the second storage box 520 is front and rear. A guide rail 513 for slidably moving in a direction, and a first storage box handle 515 for allowing a user to grasp the first storage box 510 to allow the user to pull in and out of the right storage compartment 26. do.

The guide rails 513 are provided at both side surfaces of the first storage box 510 to guide the second storage box 520 to be slidably moved in the front-rear direction.

The guide rail 513 may be provided to have a shape recessed toward the outside of the first storage box 510 at both sides of the first storage box 510.

The second storage box 520 is accommodated in the first storage box 510 and is slidably moved forward and backward. The second storage box 520 is guided along the guide rail 513 provided in the first storage box 510 to store the second storage box 520. ) And the user to grip the roller 521 and the second storage box 520 to slide in the front and rear direction in the first storage box 510 to move in the front and rear direction inside the first storage box 510. And a second storage box handle 523 which may be.

The rollers 521 are guided along the guide rails 513 provided on the lower sides of the outer sides of the second storage box 520 and provided on the first storage box 510, and the guide rails are prevented from being separated from the rollers 521. A separation prevention jaw 513a may be provided at an upper side of the 513.

Since the second storage box 520 is accommodated in the first storage box 510 and is slidably moved in the front-rear direction, the guide rails 513 provided on both sides of the first storage box 510 are stored in the second storage box. The upper edge surface of the box 520 and the roller 521 are provided at a position spaced downward from the upper edge surface of the first storage box 510 by a distance.

When the first storage box 510 is inserted into and withdrawn from the right storage compartment 26, the second storage box 520 may be introduced into and out of the right storage compartment 26 together with the first storage box 510. In addition, since the second storage box 520 is provided to be slidably moved in the front-rear direction inside the first storage box 510, the internal space of the first storage box 510 may be efficiently used.

As illustrated in FIGS. 1 and 2, a plurality of shelf units 600 may be provided inside the upper storage chamber 21 to divide the upper storage chamber 21 into a plurality.

As shown in FIGS. 35 to 39, the shelf unit 600 includes a shelf 610 including a first shelf 611 and a second shelf 613, and both side surfaces and a first shelf of the first shelf 611. Bracket 620, which is coupled to both sides of the two shelves 613, respectively, to support the first shelf 611 and the second shelf 613, and is provided on the bracket 620 to provide the first shelf 611 and the second shelf. 613 includes a horizontal holding unit 630 to keep each other horizontal.

The shelf 610 includes a first shelf 611 located on the left side of the upper storage compartment 21 and a second shelf 613 located on the right side of the upper storage compartment 21. The second shelf 613 is horizontal to each other and partitions the upper storage compartment 21.

The first protrusion 611a is provided at the front end of the right side of the first shelf 611, and the second protrusion 613a is provided at the front end of the second side of the second shelf 613 to be spaced apart from the first protrusion 611a. Can be.

The first protrusion 611a and the second protrusion 613a are spaced apart from each other, and the first protrusion 611a is twisted in the right direction or the second shelf 613 is twisted in the left direction. ) And the second protrusion 613a are in contact with each other.

When the first shelf 611 is twisted in the right direction, the first protrusion 611a is in contact with the second protrusion 613a and the first shelf 611 is no longer twisted in the right direction, and the second shelf ( When the 613 is twisted in the left direction, the second protrusion 613a is in contact with the first protrusion 611a and the second shelf 613 is no longer twisted in the left direction so that the first shelf 611 and the second The shelf 613 can be prevented from twisting in the horizontal direction.

The bracket 620 is coupled to the left side of the first shelf 611 to support the first shelf 611 and the first bracket 621 to be coupled to the right side of the first shelf 611 to the first shelf 611. ) Is coupled to the left side of the second bracket 623, the second shelf 613, the third bracket 625 to support the second shelf 613, and the right side of the second shelf 613 It is coupled to include a fourth bracket (not shown) for supporting the second shelf (613).

The bracket 620 may be supported by the support part 640 disposed between the first cold air duct 700 and the inner box 11 through the shelf unit fixing hole 713 provided in the first cold air duct 700.

Food and the like are stacked and stored on the upper part of the first shelf 611 and the second shelf 613, and the types of foods stored on the upper part of the first shelf 611 and the upper part of the second shelf 613 are different from each other. can do.

When the food stored in the upper part of the first shelf 611 and the food stored in the upper part of the second shelf 613 are different from each other, since the weight of the food is also different from each other, the first shelf 611 is used. The second shelf 613 may not be horizontal to each other, and one shelf 610 may be struck downward.

As described above, one of the first shelf 611 and the second shelf 613 is a bracket 620 for supporting the shelf 610 so that the shelf 610 is horizontal to each other without falling down. ) Is provided with a horizontal holding part 630.

The horizontal holder 630 includes a first fixing part 631 coupled to the second bracket 623 supporting the right side of the first shelf 611 and a third supporting the left side of the second shelf 613. And a second fixing part 633 coupled to the bracket 625.

The first fixing part 631 and the second fixing part 633 are coupled to the second bracket 623 and the third bracket 625 by fastening members B, respectively, and fixed to the first fixing part 631. A protrusion 631a may be provided and a fixing groove 633a may be provided in the second fixing part 633.

The first fixing part 631 is provided on the right side of the second bracket 623, the second fixing part 633 is provided on the left side of the third bracket 625, and the fixing protrusion 631a and the fixing groove ( 633a is provided at a position corresponding to each other when the first shelf 611 and the second shelf 613 are horizontal to each other.

The fixing protrusion 631a and the fixing groove 633a are provided at positions corresponding to each other, and the fixing protrusion 631a is provided to be fixed to the fixing groove 633a, so that the fixing protrusion 631a is fixed to the fixing groove ( When inserted into and fixed to 633a, the first shelf 611 and the second shelf 613 are in a horizontal state.

In addition, since the fixing protrusion 631a is fitted into the fixing groove 633a and is fixed, the first shelf 611 and the second shelf 613 are stored even if they are used for a long time in a state where different foods are stored. ) And the second shelf 613 is prevented from being struck in the downward direction so that the first shelf 611 and the second shelf 613 can be leveled.

2 to 3 and 40 to 42, the first evaporator (E1) and the first blowing fan (F1) for supplying cold air to the upper storage chamber 21 and the first cold air duct 700 and It is arranged between the inner wounds 11.

The first cold air duct 700 forms a front plate 710 in which a plurality of first cold air discharge ports 711 are provided, and a first flow path 725 which is disposed on the rear surface of the front plate 710 to move cold air. And a cold air flow passage part 720 and a first blower fan mounting part 730 provided below the cold air flow path portion 720.

The front plate 710 is made of aluminum so that the front plate 710 can be uniformly cooled by heat conduction by cold air inside the upper storage compartment 21 so that the inside of the upper storage compartment 21 can maintain a uniform temperature. do.

The front plate 710 includes a plurality of first cold air discharge ports 711 for discharging the cold air guided through the first passage 725 into the upper storage chamber 21, and a shelf unit for fixing the shelf unit 600. The fixing hole 713 is provided.

The lower portion of the front plate 710 is provided in a streamlined shape that is bent toward the upper storage compartment 21 toward the lower direction, which is adjacent to the first evaporator E1 and the first blower fan is disposed on the first evaporator E1. This is to provide a space where F1) can be installed.

Since the first blowing fan F1 is disposed below the front plate 710, the remaining portion except for the lower portion of the front plate 710 may be provided in a flat plate shape.

A partition 740 is formed below the front plate 710 to form a space in which the first evaporator E1 and the first blowing fan F1 are installed at the lower rear of the upper storage compartment 21.

The partition wall 740 forms a space for the installation of the first evaporator E1 and the first blower fan F1, and thus, the inner wall 11 rather than the distance between the first cold air duct 700 and the inner box 11. And are further spaced apart.

Therefore, the upper portion of the partition wall 740 is in close contact with the lower portion of the front plate 710 to be bent in a streamlined form, the space between the first cold air duct 700 and the partition wall 740 and the inner box 11 and the upper storage compartment 21. ) Can be sealed.

The cold air flow path part 720 is provided with a plurality of discharge holes 721a corresponding to the plurality of first cold air discharge ports 711 and the first cold air flow path part 721 disposed on the rear surface of the front plate 710, and The second cold air flow path part 723 is coupled to the first cold air flow path part 721 to form a first flow path 725 between the first cold air flow path part 721.

The first blowing fan mounting part 730 is provided below the cold air flow path part 720, and covers the housing 731 on which the first blowing fan F1 is rotatably mounted and an open front surface of the housing 731. Cover member 733 is included.

The lower part of the first evaporator (E1) is provided with a drain portion 750 for draining the condensed water generated in the first evaporator (E1), the drain portion 750 in the lower direction toward the right toward the center It is provided to have a photographic inclined surface 751, and a drainage hole 753 is provided at the end of the inclined surface 751.

The drainage hole 753 may be provided with a drain pipe 755 for draining the condensed water to the outside of the main body 10, and the drain pipe 755 may be disposed between the inner wound 11 and the outer wound 13 on the right side of the main body 10. have.

Since the drain pipe 755 is disposed between the inner trauma 11 and the trauma 13 on the side of the main body 10 and not between the inner trauma 11 and the trauma 13 on the rear side of the main body 10, the back of the main body 10. When the heat insulating material 15 is foamed into the space between the inner wound 11 and the outer wound 13, the flow of the heat insulating material 15 may be smooth, and the inner wound 11 and the trauma 13 at the rear of the main body 10 are provided. About the structure which foams the heat insulating material 15 to the space | interval between you, it will be mentioned below.

As shown in FIGS. 2 and 43, the machine room 28 provided on the rear lower side of the main body 10 may be covered by the machine room cover 29.

The machine room cover 29 includes a machine room top cover 29a that covers the front and top of the machine room 28, and a machine room back cover 29b that covers the back of the machine room 28.

Insulating material injection port 29c to be described in the drawing is shown to be provided in a position for foaming the insulating material 15 in the space between the inner wound 11 and the outer wound 13 of the main body 10, the heat insulating material 15 is Filled space will be described as the space between the inner wound (11) and the outer wound (13).

However, the heat insulating material injection port 29c may be provided at a position where the heat insulating material can be foamed inside the door 30.

Insulation 15 is foamed and filled by the foaming head 810 in the space between the inner wound 11 and the outer wound 13.

Insulation material inlet 29c is provided in the machine room upper cover 29a of the machine room cover 29 covering the machine room 28 to foam the heat insulating material 15 in the space between the inner wound 11 and the outer wound 13.

The heat insulator injection hole 29c is provided at a position corresponding to the space on the rear side of the main body 10 in order to foam the insulation 15 into the space on the rear side of the main body 10 among the spaces between the inner wound 11 and the outer wound 13. do.

The insulator inlet 29c is provided at the center of the machine room cover 29 to allow the insulator 15 foamed through the insulator inlet 29c to be evenly filled in the space between the inner box 11 and the outer box 13.

Foam head 810 connected to the insulator inlet 29c provided in the machine room upper cover 29a to foam the insulation 15 in the space between the inner wound 11 and the outer wound 13, and the inner wound 11 and the outer wound. A guide member 820 connected to the heat insulating material injection hole 29c is provided in the space between the 13.

The foaming head 810 foams the heat insulating material 15 by the heat insulating material injection hole 29c so that the heat insulating material 15 is filled in the space between the inner wound 11 and the outer wound 13.

Although only one insulation inlet 29c is provided on the drawing, and the foaming head 810 is illustrated as being configured to correspond to one, it is not limited thereto, but a plurality of insulation heads are provided to correspond to the plurality of insulation heads. It can be configured as.

When the foam head 810 is connected to the insulator inlet 29c to foam the insulator 15, the insulator 15 is foamed into the space between the inner box 11 and the outer box 13 from the insulator inlet 29c and filled. In the case of a refrigerator having a small insulating thick wall provided with a narrow space between the large refrigerator and the inner box 11 and the outer box 13, a wire (not shown) in the space between the inner box 11 and the box 13 may be formed. The obstacle prevents the flow of the heat insulator 15 so that the discharge distance of the heat insulator 15 is shortened, so that the entire space between the inner wound 11 and the outer wound 13 cannot be evenly filled.

In addition, in order to evenly fill the entire space between the inner wound 11 and the outer wound 13, the amount of the heat insulating material 15 foamed in the space between the inner wound 11 and the outer wound 13 is determined by the inner wound 11 and the outer wound 13. Over-injection should be made against the volume of space.

When the insulator 15 is over-injected, the curing time of the insulator 15 foamed into the space between the inner wound 11 and the outer wound 13 is delayed, and some of the heat insulating materials 15 are wound on the inner wound 11 and the outer wound 13. The exterior quality and quality of the refrigerator are deteriorated due to exposure to the outside of the space, and it is not only troublesome because the insulation 15 exposed to the outside of the space between the inner wound 11 and the outer wound 13 must be removed. The work time for filling the heat insulating material 15 into the space between the trauma 13 and the trauma 13 is delayed, and when the foaming head 810 is inexperienced in management, the heat insulating material cured in the space between the internal wound 11 and the trauma 13 ( A void phenomenon, which is a phenomenon in which crater-shaped pores occur on the surface of 15), may occur.

In order to prevent the above problems, the obstacle to the portion of the heat insulating material 15 that is foamed through the foam head 810 extends by a predetermined section into the space between the inner wound 11 and the outer wound 13 than the heat insulating material injection hole 29c. The guide member 820 is provided to be guided without interference.

One end of the guide member 820 is connected to the insulator inlet 29c in the space between the inner wound 11 and the outer wound 13, and the other end extends into the space between the inner wound 11 and the outer wound 13 to be foamed. Guide the heat insulating material 15 is foamed through the head 810.

As shown in FIGS. 43 to 44, the guide member 820 is a connector 821 coupled to the insulator inlet 29c, and the connector 821 so as to extend into the space between the inner wound 11 and the outer wound 13. The guide pipe 823 is connected to the).

The guide pipe 823 is formed of a hollow straight pipe to form a heat insulating material 15 foamed from the foaming head 810 within the space between the inner wound 11 and the outer wound 13 by the length of the guide pipe 823. And guides without interference of the inside of the space between the trauma 13.

The initial discharge position of the heat insulating material 15 foamed from the foam head 810 by the guide pipe 823 is the space between the inner wound 11 and the outer wound 13 by the length of the guide pipe 823 at the heat insulating material injection hole 29c. Since the initial discharge position of the heat insulator 15 extends from the lower end of the rear of the main body 10 to the center portion, the interference caused by the obstacle in the space between the inner wound 11 and the outer wound 13 is minimized, and the guide Since the high pressure of the heat insulating material 15 is maintained while passing through the inside of the pipe 823, the entire space between the inner wound 11 and the outer wound 13 can be evenly filled with the heat insulating material 15. The injection volume can be minimized.

In addition, the insulating material 15 is cured in the space between the inner wound 11 and the outer wound 13 by the surface friction during foaming of the heat insulating material 15 so as to prevent the void phenomenon occurring on the surface of the heat insulating material 15. Since the injection amount of the heat insulator 15 can be minimized, the heat insulator 15 is not exposed to the outside, thereby reducing the work time.

As illustrated in FIG. 45, the guide member 830 may be integrally provided with the connector 831 and the guide pipe 833, and may be coupled to the insulator inlet 29c.

Except that the connector 831 and the guide pipe 833 are integrally provided, like the guide member 820 illustrated in FIG. 4, since the guide pipe 833 is provided with a hollow straight pipe, description thereof will be omitted. .

46 to 47, the guide pipe 825 is formed of a hollow straight pipe and is connected to the connector 821 and the first guide pipe 827 and the branch which is branched from the first guide pipe 827. It may be provided to include a two guide pipe (829).

The second guide pipe 829 allows the heat insulating material 15 passing through the first guide pipe 827 to branch and spread in two directions so as to efficiently fill the entire space between the inner wound 11 and the outer wound 13. have.

The guide pipe 825 including the first guide pipe 827 and the second guide pipe 829 has a hollow Y shape as a whole.

As illustrated in FIG. 48, the guide member 830 is integrally provided with the connector 831 and the guide pipe 835 to be coupled to the insulator inlet 29c, and the guide pipe 835 is provided to have a hollow Y shape. Can be.

Like the guide pipe 825 shown in FIG. 46, the guide pipe 835 is formed of a hollow straight pipe and is branched from the first guide pipe 837 and the first guide pipe 837, which are connected to the connector 831. It may be provided to include a second guide pipe (839).

As described above, when the heat insulating material 15 is foamed into the space between the inner wound 11 and the outer wound 13, the guide members 820 and 830 may be used so that the flow of the heat insulating material 15 is not disturbed. As shown in FIG. 49, instead of using the guide members 820 and 830, a drain pipe for draining the condensed water generated from the refrigerant pipe P or the first evaporator E1 through which the refrigerant flows to the outside of the main body 10 ( 755 is disposed between the inner wound 11 and the outer wound 13 on the side of the main body 10 so that the heat insulating material 15 foams into the space between the inner wound 11 and the outer wound 13 on the rear of the main body 10. When it is possible to prevent the flow of the heat insulating material (15).

In the above description of the refrigerator with reference to the accompanying drawings, a specific shape and direction have been described mainly, but various modifications and changes are possible by those skilled in the art, and such modifications and changes should be interpreted as being included in the scope of the present invention. do.

10: body 11: inner box
13: trauma 13a: electric box mounting hole
15: insulation 17: partition
17a: Partition 1 17b: Partition 2
19: vacuum insulation
20: storage room 21: upper storage room
23: lower storage room 25: left storage room
26: right storage compartment 26a: coupling portion
27: storage container 28: machine room
29: machine room cover 29a: machine room top cover
29b: Machine room rear cover 29c: Insulation hole
30: door 31: door guard
40: hinge unit 41: upper hinge
41a: hinge hole 43: intermediate hinge
100, 130: reinforcing member 110: first reinforcing member
120: second reinforcing member
200: reinforcement frame 210: upper reinforcement frame
220: intermediate reinforcement frame 230: lower reinforcement frame
240: first side reinforcement frame 250: second side reinforcement frame
300: battlefield box 310: base
311: base portion 313: fixed hook
313a: first fixing hook 313b: second fixing hook
315: wire through hole 317: receiving groove
320: cover 321: hinge cover
330: printed circuit board 331: electronic components
333: wire 335: wire connector
340: printed circuit board mounting portion 341: connector coupling portion
350: reinforcement plate
400: heat dissipation pipe 410: seating part
420: fixing groove 421: first fixing groove
423: second fixing groove 430: clip
431: First Government Government 433: Second Government Government
500: storage unit 510: first storage unit
511: coupling groove 513: guide rail
513a: release prevention jaw 515: handle of the first storage box
520: second storage box 521: roller
523: handle of the second storage box
530: sliding shelf 540: slide unit
541: sliding part 541a: engaging projection
543: slide rail
550: Cover Rail 551: Fastening Hole
553: locking member
560: self-closing device
570: Case 571: Information rail
571a: straight line 571b: locking portion
573: guide portion 575: fixed portion
577: first accommodating part 579: second accommodating part
579a: Jamming jaw
580: elastic unit 581: slider
581a: Rotating hole 581b: First fixing groove
581c: second fixing groove 583: rotator
583a: protrusion 583b: rotation axis
583c: locking groove 585: elastic member
590 oil damper 591 body part
593 flow part
600: shelf unit 610: shelf
611: first lathe 611a: first protrusion
613: second shelf 613a: second projection
620: bracket 621: first bracket
623: second bracket 625: third bracket
630: Horizontal Maintenance Department 631: First Government
631a: fixed protrusion 633: second fixed part
633a: fixing groove
640 support part
700: first cold air duct 710: front panel
711: First cold air outlet 713: Shelf unit fixing hole
720: cold air flow passage 721: first cold air flow passage
721a: discharge hole 723: second cold air flow passage part
725: the first euro
730: first blowing fan mounting portion 731: housing
733: cover member 740: partition wall
750: drain portion 751: slope
753: drainage hole 755: drainage pipe
760: second cold air duct 761: second cold air air outlet
763: the second euro
810: foam head 820, 830: guide member
821, 831: Connectors 823, 825, 833, 835: Guide Pipe
827, 837: first guide pipe 829, 839: second guide pipe
C: Compressor E: Evaporator
E1: first evaporator E2: second evaporator
F: Blowing Fan F1: 1st Blowing Fan
F2: Second blower fan D: Cold duct
P: Refrigerant pipe S: Receiving space
B: fastening member

Claims (12)

A main body including an inner wound in which a storage compartment is formed and an outer wound coupled to an outer side of the inner wound to form an outer appearance;
A heat dissipation pipe fixed to the front edge of the inner shell to prevent dew condensation generated on the outer shell;
A seating portion provided on the front edge of the inner phase to seat the heat dissipation pipe;
A fixing groove provided in the seating part; And
A clip fixed to the fixing groove to accommodate the heat dissipation pipe therein so that the heat dissipation pipe is fixed to the seating part;
Including,
The fixing groove includes a first fixing groove and a second fixing groove to which both ends of the clip are inserted and fixed, respectively.
And the clip includes a first fixing part inserted into and fixed to the first fixing groove, and a second fixing part inserted into and fixed to the second fixing groove. The method of claim 1,
The seating portion is a refrigerator, characterized in that provided in the end of the front edge of the inner box to be provided in a position adjacent to the trauma when the inner wound and the trauma is combined. The method of claim 2,
And the seating part is provided at an end of the front edge of the inner box, and the heat dissipation pipe seated on the seating part is disposed at a position spaced apart from the inside of the storage compartment. The method of claim 3, wherein
And the heat dissipation pipe is disposed at a position spaced apart from the inside of the storage compartment so that high temperature heat transmitted by the high temperature refrigerant flowing into the heat dissipation pipe is reduced into the storage compartment. The method of claim 3, wherein
Since the heat dissipation pipe is disposed at a position adjacent to the trauma, the temperature difference between the inside and the outside of the trauma is reduced by the high temperature heat caused by the high temperature refrigerant flowing into the heat dissipation pipe, resulting in dew condensation generated on the outer surface of the trauma. Refrigerator, which is prevented. delete delete delete delete delete delete delete

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