KR20120037269A - Insulation glass panel for improving performance and refrigerator having the same - Google Patents

Abstract

PURPOSE: An insulating glass panel and a refrigerator having the same are provided to form a heat flow path between laminated insulating glasses and extend the heat flow path enough so that a heat insulation property is efficiently enhanced. CONSTITUTION: An insulating glass panel comprises a pair of insulating glasses(210), a plurality of spacers(220), and a sealing unit. The pair of the insulating glasses is laminated with a predetermined gap. The spacers support the pair of the insulating glasses at multiple points of a supporting area formed in a vacuumized layer between the pair of the insulating glasses. The sealing unit is closely adhered to an edge of the pair of the insulating glasses to be corresponded to a width between the pair of the insulating glasses. The sealing unit forms a heat flow path between the pair of the insulating glasses and tightly seals the supporting area from outside.

Description

INSULATION GLASS PANEL FOR IMPROVING PERFORMANCE AND REFRIGERATOR HAVING THE SAME}

The present invention relates to a heat insulating glass panel and a refrigerator having the same, and more particularly, by increasing the heat flow path from one side of the insulating glass having a vacuum layer to the other side to efficiently reduce the heat transferred to improve heat insulating performance. It relates to a heat insulating glass panel and a refrigerator having the same to improve the heat insulating performance.

Typically a refrigerator is a device used to freeze or store food at a low temperature for a period of time, and a refrigeration cycle device that generates cold air is generally installed inside the device.

Therefore, since the refrigerator having the freezing and refrigerating functions as described above achieves a predetermined temperature or less than the outside temperature, the refrigerator must be provided with an insulation function so that the temperature inside the refrigerator is not affected by the external temperature environment.

In general, in order to perform the thermal insulation function, a conventional thermal insulation foam was used.

Here, the refrigerator includes a wall constituting the main body and partition walls partitioning the freezer compartment and the refrigerating compartment, and the insulation foam is formed by foaming the inner space of the wall and the partition walls in the inner space.

Accordingly, the foamed thermal insulation foam can lower the heat transfer rate of the external heat is transferred to the internal space of the refrigerator.

However, in the case of foaming the insulating foam inside the wall as described above, the foamed foam itself may be deformed, such as shrinkage caused by the external environmental change for a long time, and this causes a problem that its thermal insulation function is considerably reduced. have. Accordingly, there is a problem that is the main cause of lowering the refrigeration performance of the refrigerator as it does not perform the heat transfer prevention function of the insulating foam itself.

In order to solve the problem of the above insulation foam, it is embedded in the wall of the refrigerator, forming a vacuum layer in the buried space to effectively block the heat transfer, and the heat transferred from the wall of the refrigerator flows to the inner wall side. In order to minimize the heat transmitted to the outside during the flow to improve the heat insulating performance, and thereby to develop a heat insulating panel that can improve the freezing performance of the refrigerator.

The present invention has been made to solve the above problems, an object of the present invention is to form a heat flow path between the insulating glass laminated to each other so that the vacuum layer is formed, and extend the heat flow path sufficiently in one side of the insulating glass It is to provide a heat insulating glass panel and a refrigerator having the same to improve the heat insulating performance that can reduce the heat transferred to the other side of the heat insulating glass more than a certain amount efficiently.

In one aspect, the present invention provides an insulated glass panel that improves heat insulating performance.

The insulating glass panel is a pair of insulating glass laminated with a predetermined gap from each other; A plurality of spacers for supporting the pair of heat insulating glasses in a support region formed in a vacuum layer between the pair of heat insulating glasses; And a sealing part disposed in close contact with an edge surface of the pair of insulating glasses so as to correspond to a width between the pair of insulating glasses, forming a heat flow path between the pair of insulating glasses, and sealing the support area from the outside. Include.

Here, it is preferable that the said sealing part is any one of the sealant which consists of epoxy, or frit glass.

In addition, the sealing portion, the outer edge portion of the sealing portion is preferably formed of any one of a right angle or a predetermined curvature.

Moreover, the said sealing part may have a straight contact surface in close contact with the edge surface of a pair of heat insulation glass, and the protrusion surface protruding convexly outward from the said contact surface from the said contact surface.

In addition, a plurality of hot spots for heat radiation may be further formed on the outer surface of the sealing portion other than the portion in contact with the edge surface of the pair of insulating glasses.

In addition, a coupling groove having a predetermined depth therein is further formed on an edge surface of the pair of insulating glass, and the sealing portion may be further formed with a coupling protrusion coupled to the coupling groove.

In addition, the edge of the pair of insulating glass, a coupling protrusion to protrude a predetermined length to the outside is further formed, the sealing portion may be further formed with a coupling groove to which the coupling protrusion is fitted.

In another aspect, the present invention provides a refrigerator having a heat insulating glass panel that improves heat insulating performance.

The refrigerator includes a main body having a refrigerator compartment and a freezer compartment partitioned from each other and having an outer wall; Doors installed at one side of the main body to open and close the refrigerating compartment and the freezing compartment; And embedded in the outer wall and the door, wherein a plurality of insulating glasses are stacked to form one or a plurality of vacuum layers, and are arranged to be in close contact with edges of the insulating glasses to seal the vacuum layer from the outside. And an insulating glass panel having a seal to form a heat flow path between the glasses.

Here, it is preferable that the said sealing part is any one of the sealant which consists of epoxy, or frit glass.

In addition, the sealing portion, the outer edge portion of the sealing portion is preferably formed of any one of a right angle or a predetermined curvature.

Moreover, the said sealing part may have a straight contact surface in close contact with the edge surface of a pair of heat insulation glass, and the protrusion surface protruding convexly outward from the said contact surface from the said contact surface.

In addition, a plurality of hot spots for heat radiation may be further formed on the outer surface of the sealing portion other than the portion in contact with the edge surface of the pair of insulating glasses.

In addition, a coupling groove having a predetermined depth therein is further formed on an edge surface of the pair of insulating glass, and the sealing portion may be further formed with a coupling protrusion coupled to the coupling groove.

In addition, the edge of the pair of insulating glass, a coupling protrusion to protrude a predetermined length to the outside is further formed, the sealing portion may be further formed with a coupling groove to which the coupling protrusion is fitted.

The present invention forms a heat flow path between the insulating glass laminated to each other so that a vacuum layer is formed, and extends the heat flow path sufficiently to reduce the heat transferred from one insulating glass to the other insulating glass to a certain level or more to efficiently heat insulation performance. It has an effect that can be improved.

1 is a perspective view showing a refrigerator having a heat insulating glass panel of the present invention.
2 is a plan view showing an insulating glass panel of the present invention.
3 is a side view showing an insulating glass panel of the present invention.
4 is a cross-sectional view showing another example of a sealing part according to the present invention.
5 is a cross-sectional view showing another example of a sealing part according to the present invention.
6 is a cross-sectional view showing an insulating glass panel with an example of the joining means according to the invention.
7 is a sectional view showing an insulating glass panel with another example of a joining means according to the invention.
8 is a plan view showing that the joining means according to the invention is formed in a single line.
9 is a plan view showing that the coupling means according to the invention is formed in multiple lines.
10 is a plan view showing that the joining means according to the invention is formed in an intersecting line.

Hereinafter, with reference to the accompanying drawings, it will be described a heat insulating glass panel of the present invention and a refrigerator having the same.

1 to 3, the insulating glass panel 200 of the present invention is installed on the outer wall and the door 120 of the main body 110 of the refrigerator 100 to serve to insulate the internal space of the refrigerator 100. do.

Therefore, the configuration and operation of the insulating glass panel 200 will be described including the configuration and operation of the refrigerator 100.

1 and 3, the refrigerator 100 of the present invention includes a main body 110 and one or a plurality of doors 120 that open and close an inner space of the main body 110.

The inside of the main body 110 is provided with a freezing compartment (a) and a refrigerating compartment (b) partitioned through the partition wall 130. In addition, the main body 110 is provided with a machine room (not shown) in which a refrigeration cycle device (not shown) is installed to provide cold air to the freezing chamber (a). Here, the machine room is also installed in the main body 110 to be partitioned through the partition wall different from the freezing chamber (a) and the refrigerating chamber (b).

In addition, the door 120 is connected to the hinge (H) to rotate the opening and closing portion of the main body 110, a plurality of the opening and closing the freezer compartment (a) and the refrigerating compartment (b) by the rotation opening and closing independently. It is made up of. In FIG. 1, as a double door type, two doors 120 are provided as an example.

As described above, the main body 110 and the doors 120 according to the present invention are insulated glass panels 200 to prevent heat transfer between the freezing compartment a and the refrigerating compartment b therein with a relatively high temperature external environment. Has

That is, the insulating glass panel 200 may be embedded in the outer wall of the main body 110 and the inside of the door 120.

Insulating glass panel 200 of the present invention is a member that performs a heat insulating function, the heat is formed by extending the length of the heat flow path that the heat from the outside of the relatively high temperature body is transferred from one side to the other side of the heat insulating glass panel It is to be sufficiently discharged, thereby lowering the heat transfer rate can improve the thermal insulation performance.

1 to 7, the structure and operation of the insulating glass panel 200 of the present invention will be described.

2 and 3, the insulating glass panel 200 of the present invention is a pair of insulating glass 210 and a pair of insulating glass panel 210 disposed in a state of being laminated with a predetermined gap between each other. A plurality of spacers 220 arranged at a plurality of positions between the plurality of spacers 220 to support the pair of insulating glasses 210, and arranged along the edge of the pair of insulating glasses 210. The sealing part 300 which seals the space between glass 210 is airtight.

In addition, each of the pair of insulating glasses 210 may have a predetermined thickness and may be made of tempered glass having a predetermined strength or more.

Here, the space between the pair of insulating glass 210 is a space in which the vacuum layer VL is formed, and the support area SA having a predetermined boundary is formed in the vacuum layer VL. The support area SA is formed by arranging the plurality of spacers 220.

One end of the plurality of spacers 220 is fixed to the inner surface of one insulating glass 210, the other end is fixed to the inner surface of the other insulating glass 210, thereby the pair of insulating glass ( The 210 may form a stacked structure in a state of forming a predetermined gap therebetween.

Here, the spacers 220 may be made of a stainless material having a certain strength, as well as the length of each other so as to achieve the clearance.

Accordingly, the vacuum layer VL between the pair of insulating glass 210 may be hermetically sealed by the sealing part 300 according to the present invention, and thus, between the pair of insulating glass 210. The vacuum layer VL may be in a vacuum state.

In the state in which the insulating glass panel 200 is embedded in the main body 110 and the door 120 of the refrigerator, it prevents the loss due to heat transfer, and thus the heat insulating performance may not be reduced.

This may be achieved by the sealing layer 300 according to the present invention the vacuum layer (VL).

In addition, a low radiation coating may be further formed on the outer surface of the insulating glass 210. Accordingly, it is possible to efficiently reduce heat transfer due to radiant heat.

In particular, the sealing unit 300 in the present invention forms the vacuum layer (VL) while surrounding the edge of the pair of insulating glass (210). Here, the sealing part 300 is disposed in close contact with the edge surface of the pair of insulating glass 210.

Accordingly, the overall width WS of the sealing part 300 may be the same as the outer width W between the pair of insulating glasses 210.

Therefore, the heat transferred from one of the heat insulating glass (upper heat insulating glass 210a) of the pair of heat insulating glass 210 passes through the sealing part 300 and the other heat insulating glass (lower heat insulating glass 210b). It can flow along the heat flow path (F) to be transferred to.

In particular, since the sealing part 300 according to the present invention is disposed in close contact with the edge surface along the edge of the pair of insulating glass 210, the heat transferred from the upper insulating glass 210a is the upper insulating The sealing unit 300 is in close contact with the edge side of the glass 210a.

Then, the heat transferred to the sealing part 300 flows to the lower side insulating glass 210b, and emits some heat.

That is, since the length of the sealing portion 300 up and down, that is, the above-mentioned width (WS) is formed longer than the width (W) between the pair of insulating glass 210, heat during heat flow The time of release can be further increased. Here, the width WS of the sealing part 300 may be proportional to the time of heat release. In addition, the sealing part 300 may be attached to be in close contact with the edge surface of the pair of insulating glass 210. For this reason, heat is transmitted to the sealing part 300 through the edge side of the upper insulating glass 210a, and heat transferred to the sealing part 300 is transferred to the lower insulating glass (edge) through the edge side of the lower insulating glass 210b. 210b).

Accordingly, since some heat is continuously emitted from the sealing part 300, the heat transferred to the lower insulating glass 210b may be lowered below a predetermined temperature than the temperature of the heat flowing from the upper insulating glass 210a.

Here, it may be made of any one of an epoxy-based sealant or frit glass.

On the other hand, Figure 4 shows that a certain curvature is formed in the outer edge portion of the sealing portion 300 '.

Referring to FIG. 4, the sealing part 300 ′ according to the present invention is disposed to be in close contact with the edge surfaces of the pair of insulating glass 210 forming the vacuum layer VL therebetween, and the sealing part 300. A constant curvature R is formed at the outer edge of ').

Here, the heat flow path F connects the upper insulating glass 210a and the sealing portion 300 'corresponding to the width W of the pair of insulating glass 210 and the lower insulating glass 210b.

Therefore, the heat transferred to the upper insulating glass 210a is transferred to the lower insulating glass 210b through the sealing part 300 ', and in particular, while passing through the sealing part 300', a part of the heat is transferred to the outer side. It may be emitted to spread to the outside in the curvature (R) of the corner portion.

Accordingly, since the heat transmitted to the lower insulating glass 210b is substantially released from the sealing portion 300 ′, the temperature may be lower than the predetermined heat than the heat from the upper insulating glass 210a. That is, the heat transfer rate of the insulating glass panel may be lowered by the sealing part 300 ′ having the curvature R formed at the outer edge portion as described above. Accordingly, the thermal permeability of the insulating glass panel of the present invention can be lowered and the thermal insulation performance can be improved.

On the other hand, Figure 5 shows that the outer portion of the sealing portion 300 "protrudes convex.

Referring to FIG. 5, the sealing part 300 ″ according to the present invention forms a vacuum layer VL in a state in which the sealing part 300 ″ is in close contact with the edge surfaces of the pair of insulating glass 210, and the sealing part 300 ″. The width WS up and down) is formed to correspond to the width W between the outer surfaces of the pair of insulating glass 210.

And, the sealing portion 300 "is a straight contact surface (S1) in close contact with the edge surface of the pair of heat insulating glass 210 and from the contact surface (S1) to the outside of the heat insulating glass 210. It has a protruding surface S2 which protrudes convexly.

Here, the heat flow path F is formed to connect the upper insulating glass 210a, the sealing portion 300 "and the lower insulating glass 210b.

Therefore, the heat transferred to the upper insulating glass 210a is transferred to the sealing part 300 ", and the heat transferred to the sealing part 300" is transferred to the lower insulating glass 210b.

At this time, since the outer surface of the sealing portion 300 "according to the present invention forms a protruding surface S2 protruding to the outside, the sealing during the transfer from the upper insulating glass 210a to the lower insulating glass 210b. The transfer time of heat in section 300 "can be increased beyond a certain amount. Therefore, the heat transferred to the sealing part 300 ″ may be released to the outside more than a predetermined time during the increased transfer time of the heat.

In addition, as the outer surface of the sealing portion 300 "forms a protruding surface S2 having a convex curvature, the angle emitted to the outside of the heat flowing in the sealing portion 300" is formed to spread in all directions. Accordingly, heat dissipation of heat flowing from the sealing part 300 ″ by the protruding surface S2 having the convex curvature may be easily performed.

In addition, although not shown in the drawings, a plurality of hot spots may be formed on the outer surface of the sealing parts 300, 300 ′ and 300 ″ to induce heat dissipation.

Here, the sealing parts 300, 300 ', 300 "according to the present invention may be made of an epoxy-based sealant having non-conductive properties. In addition, it is preferable to have a constant elasticity, and to be cured by heating at a constant heating temperature and to lower the temperature. As a result, there is no shape deformation.

Accordingly, the sealing parts 300, 300 ', 300 "in the present invention is preferably made of an epoxy series sealing parts 300, 300', 300" having a thermosetting property.

Here, the epoxy-based sealing portion (300, 300 ', 300 ") may be cured at a heating temperature of 50 to 100 degrees Celsius.

In particular, the outer surface of the sealing portion and the edge side outer surface of the pair of insulating glass 210 may form a continuous surface with each other. Preferably, the outer surfaces of the sealing portions 300, 300 ′ and 300 ″ and the outer surfaces of the pair of insulating glass 210 may form the same line with each other.

In this state, when the sealing unit 300, 300 ', 300 "is exposed to a heating temperature environment of 50 to 100 degrees Celsius, the sealing unit 300, 300', 300" is cured in a batch shape as described above Is done.

Therefore, since the sealing parts 300, 300 ′, and 300 ″ according to the present invention are made of a thermosetting epoxy series, the shape may be maintained after thermal curing. The space between the pair of insulating glasses 210 is maintained. Since it may be hermetically sealed by the sealing parts 300, 300 ′, and 300 ″, the vacuum layer VL may be formed in a predetermined gap with the plurality of spacers 220.

The insulating glass panel 200 manufactured as described above is embedded in the body 110 and the doors 120 of the refrigerator 100.

Since the vacuum layer VL of the buried insulating glass panel 200 is hermetically sealed by the sealing part 300 according to the present invention, the temperature of the refrigerator 100 is higher than the inside of the refrigerator 100. The heat transfer to the inside can be reduced below a certain level.

Preferably, the heat transmission rate of the insulating glass panel 200 may be 0.8 W / m 2 .K or less.

In addition, the width length in the width direction along the insulating glass 210 of the sealing portion 300, 300 ', 300 "as described above is preferably determined in the range of 1 to 10mm.

Meanwhile, referring to FIGS. 6 and 7, the present invention may further include a coupling means 10 that couples the pair of insulating glass 210 and the heat-cured sealing part to each other.

Figure 6 shows an example in which the coupling means 10 according to the present invention is formed in the shape of grooves and protrusions.

Referring to FIG. 6, a coupling groove 211 having a predetermined length and having a predetermined depth may be formed on the inner side surface of the pair of insulating glasses 210. In addition, the sealing part 300 disposed at the position where the coupling groove 211 is formed may have a coupling protrusion 301 fitted into the coupling groove 211.

Herein, the coupling protrusion 301 of the sealing part 300 may be deformed to be fitted into the coupling groove 211 during the heat curing process. Therefore, the coupling protrusion 301 may be generated in the heat curing process and tightly fixed to each other by being fitted into the coupling groove 211.

Figure 7 shows another example in which the coupling means 20 according to the present invention is formed in the shape of grooves and protrusions.

Referring to FIG. 7, a coupling protrusion 212 having a predetermined length and having a predetermined depth may be formed on the inner side of the edge of the pair of insulating glasses 210. In addition, the sealing part 300 disposed at a position where the coupling protrusion 212 is formed may have a coupling groove 302 into which the coupling protrusion 212 is fitted.

Herein, the coupling groove 302 of the sealing part 300 may be deformed to be fitted to the coupling protrusion 212 during the heat curing process. Thus, the coupling grooves 302 may be generated in the thermosetting process and fitted into the coupling protrusions 212 to be tightly fixed to each other.

In particular, FIGS. 8 to 10 show various forms of coupling means having a predetermined length or formed in a line shape as described above.

As shown in FIG. 8, the coupling means 10 and 20 as shown in FIGS. 6 and 7 may be formed in a line along the edge of the pair of insulating glass 210, as shown in FIG. 10. As shown in FIG. 11, the coupling means 10 and 20 may be formed in a pair of lines, and as illustrated in FIG. 11, the coupling means 10 and 20 may be formed in a zigzag shape to cross each other. It may be formed in a line.

Accordingly, as the coupling means 10 and 20 form lines in various manners as described above, the airtightness in the vacuum layer VL may be further improved, and the bonding force between the insulating glasses 210 may be further improved. Of course, it may also reduce the heat transfer rate.

10, 20: coupling means
100: refrigerator
110:
120: door
200: insulating glass panels
210: insulating glass
210a: upper multi-row glass
210b: lower insulation glass
220: spacer
300, 300 ', 300 ": Sealing part
211, 310: Coupling protrusion
212, 320: coupling groove
VL: vacuum layer
SA: support area
F: heat flow path

Claims (15)

A pair of insulating glass laminated at a constant gap with each other;
A plurality of spacers for supporting the pair of heat insulating glasses in a support region formed in a vacuum layer between the pair of heat insulating glasses; And
A sealing part disposed in close contact with an edge surface of the pair of insulating glasses so as to correspond to a width between the pair of insulating glasses, forming a heat flow path between the pair of insulating glasses, and sealing the supporting area from the outside. Insulating glass panel to improve the insulating performance, characterized in that. The method of claim 1,
The said sealing part is either a sealant which consists of epoxy, or a frit glass, The heat insulation glass panel which improves the heat insulation performance characterized by the above-mentioned. The method of claim 1,
The sealing unit,
The outer edge portion of the sealing portion is formed of any one of a right angle or a curvature of the insulating glass panel to improve the thermal insulation performance. The method of claim 1,
The sealing unit,
The heat insulation glass panel which improves heat insulation performance, characterized by having a straight contact surface in close contact with the edge surface of the pair of heat insulation glass, and a protruding surface protruding convexly outward from the contact surface from the contact surface. The method of claim 1,
Insulating glass panel to improve the insulating performance, characterized in that a plurality of hot spots for heat radiation is further formed on the outer surface of the sealing portion other than the portion in contact with the edge surface of the pair of insulating glass. The method of claim 1,
On the edge surface of the pair of insulating glass, a coupling groove having a predetermined depth inward is further formed,
The sealing unit, the insulating glass panel to improve the heat insulating performance, characterized in that the coupling projection is inserted into the coupling groove is further formed. The method of claim 1,
On the edge surface of the pair of heat-insulating glass, a coupling protrusion which protrudes a predetermined length outward is further formed,
The sealing portion, the insulating glass panel to improve the heat insulating performance, characterized in that the coupling groove is further formed by engaging the coupling projection. A refrigerator compartment and a freezer compartment which are partitioned from each other and having an outer wall;
Doors installed at one side of the main body to open and close the refrigerating compartment and the freezing compartment; And
It is embedded in the outer wall and the door, a plurality of insulating glass is laminated to form one or a plurality of vacuum layer, is arranged to be in close contact with the rim surface of the insulating glass to seal the vacuum layer from the outside, the insulating glass A refrigerator having a heat insulating glass panel that improves heat insulating performance, including a heat insulating glass panel having a sealing portion forming a heat flow path therebetween. The method of claim 8,
A pair of insulating glass laminated at a constant gap with each other;
A plurality of spacers for supporting the pair of heat insulating glasses in a support region formed in a vacuum layer between the pair of heat insulating glasses; And
The sealing part is disposed in close contact with the edge surface of the pair of heat insulating glasses so as to correspond to the width between the pair of heat insulating glasses, and forms a heat flow path between the pair of heat insulating glasses, and seals the support area from the outside. Insulating glass panel which improves the heat insulation performance characterized by including. The method of claim 9,
The said sealing part is either a sealant which consists of epoxy, or a frit glass, The heat insulation glass panel which improves the heat insulation performance characterized by the above-mentioned. The method of claim 9,
The sealing unit,
The outer edge portion of the sealing portion is formed of any one of a right angle or a curvature of the insulating glass panel to improve the thermal insulation performance. The method of claim 9,
The sealing unit,
The heat insulation glass panel which improves heat insulation performance, characterized by having a straight contact surface in close contact with the edge surface of the pair of heat insulation glass, and a protruding surface protruding convexly outward from the contact surface from the contact surface. The method of claim 9,
Insulating glass panel to improve the insulating performance, characterized in that a plurality of hot spots for heat radiation is further formed on the outer surface of the sealing portion other than the portion in contact with the edge surface of the pair of insulating glass. The method of claim 9,
On the edge surface of the pair of insulating glass, a coupling groove having a predetermined depth inward is further formed,
The sealing unit, the insulating glass panel to improve the heat insulating performance, characterized in that the coupling projection is inserted into the coupling groove is further formed. The method of claim 9,
On the edge surface of the pair of heat-insulating glass, a coupling protrusion which protrudes a predetermined length outward is further formed,
The sealing portion, the insulating glass panel to improve the heat insulating performance, characterized in that the coupling groove is further formed by engaging the coupling projection.

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