RU2443950C2 - Refrigerator - Google Patents

Abstract

FIELD: personal use articles.

SUBSTANCE: refrigerator comprises a body formed by the inner and outer bodies and the foam material filling the space between the outer and inner bodies. The engine space is formed in the rear lower part of the body. Between the inner and outer bodies in front of the engine space there is a vacuum insulation panel, passing along the bottom of the refrigerator body and further along the inclined section of the refrigerator body forming the engine space. The panel is attached to the bottom of the outer body from the refrigerator body bottom. The panel is located from the side of the inclined section of the refrigerator body; and the thermal insulating mat is placed between the inclined section of the outer body and the vacuum insulation panel. This mat comprises a part that fills the lower space without insertion of foam insulation material.

EFFECT: receiving satisfactory characteristics of thermal insulation in the inclined section of the body with secure fastening in this section of the vacuum insulation panel.

5 cl, 6 dwg

Description

BACKGROUND OF THE INVENTION

Technical field

The invention relates to a refrigerator in which a vacuum insulation panel is used.

State of the art

The capacity of refrigerators has recently increased, and the thickness of the heat-insulating wall of the refrigerator case is reduced in order to increase the capacity of the refrigerator. However, conventional refrigerators have insufficient thermal insulation of parts subject to strong temperature effects from the outside, such as the periphery of the engine room, where the compressor is located, which carries out the refrigeration cycle and generates heat. In view of this problem, for example, Japanese Patent JP-A-2006-90650 discloses a refrigerator in which a vacuum insulating panel is used in parts exposed to strong thermal effects from the outside. The vacuum insulation panel is thin and has high thermal insulation characteristics.

The vacuum insulation panel contains a core made by forming a heat-insulating mat from a bundle of thin fiberglass or glass wool. The core is placed in a gas-insulating vessel made of a multilayer film consisting of aluminum foil and synthetic resin and forming a bag. A vacuum is created in the gas-insulating vessel, and its opening is closed so that the interior of the vessel remains in a state of vacuum or rarefied pressure. The vacuum insulation panel is thin and maintains low thermal conductivity (i.e., it has thermal insulation characteristics).

The above-described vacuum insulating panel is used in a refrigerator including an outer casing, an inner casing housed inside the outer casing, and foam insulation, such as polyurethane foam, which fills the gap between the inner and outer casings. The engine room is provided down and behind the refrigerator. The vacuum insulation panel extends from the bottom of the refrigerator body to an inclined section in front of the refrigerator body.

In the above construction, the vacuum insulation panel is attached to the bottom of the outer casing with double-sided adhesive tape, from the bottom of the refrigerator casing. On the side of the inclined portion of the refrigerator body, a plurality of ventilation holes are made in the inclined surface of the outer case. Many small spacers are attached to the inclined surface with double-sided tape around the ventilation holes. The vacuum insulation panel is attached to the spacer elements with double-sided adhesive tape. In other words, the vacuum insulation panel is attached by means of spacers to the inclined surface of the outer casing bypassing the ventilation openings. The aforementioned ventilation openings are used to exhaust gas from the housing when the gap between the inner and outer casings is filled with foam insulation material. To this end, a plurality of spacer elements, each of which has the shape of a relatively small roller, are located around the ventilation openings. However, the spacer elements, despite their small size, interfere with filling the gap between the inner and outer bodies with foam insulation material. In particular, it is difficult to fill the gap to the bottom of the inclined portion of the refrigerator body in front of the engine room. As a result, a sufficient amount of insulating material does not enter the space around the periphery of the vacuum insulation panel, therefore, the thermal insulation characteristics are insufficient.

In this case, it is believed that reducing the size of the spacer elements reduces the size of the gaps in the filling with foam insulation material. However, further reduction in the size of the spacer elements will reduce the fastening strength of the vacuum insulation panel.

SUMMARY OF THE INVENTION

Therefore, the technical objective of the present invention is to provide a refrigerator in which the vacuum insulation panel extends from the bottom of the refrigerator body to the inclined portion in front of the refrigerator body, and which makes it possible to obtain satisfactory thermal insulation characteristics in the inclined portion, wherein the vacuum insulation panel can be securely fixed in the inclined plot.

The present invention provides a refrigerator comprising a housing formed by an inner and outer shells and foam material filling a gap between the outer and inner shells; engine room formed in the rear lower part of the housing; and a vacuum insulation panel provided in the gap between the inner and outer bodies in front of the engine room and extending along the bottom of the refrigerator body and further along the inclined portion of the refrigerator body forming the engine room, the vacuum insulation panel being attached to the bottom of the outer case from the bottom of the refrigerator body; the vacuum insulation panel extends from the side of the inclined portion of the refrigerator body, and the heat insulation mat is placed between the inclined portion of the outer case and the vacuum insulation panel; and the heat-insulating mat includes a part filling the lower gap without introducing foam insulating material.

BRIEF DESCRIPTION OF THE accompanying drawings

Figure 1 is a partial view of the refrigerator according to the first embodiment of the invention in longitudinal side section along line 1-1 in Figure 2.

Figure 2 - local front view of the refrigerator with the removed inner case.

Figure 3 is a partial view of the refrigerator in cross section along line 3-3 in Figure 2.

Figure 4 is a perspective view with a spatial separation of the parts of the vacuum insulation panel, heat insulation mat, as well as the lower and inclined sections of the outer casing.

5 is a partial view of the refrigerator according to the second variant of implementation in longitudinal side section along the line 5-5 in figure 2.

6 is a view similar to Figure 5, which shows a third embodiment.

DETAILED DESCRIPTION

A first embodiment will be described with reference to FIGS. 1-4. Figure 1 shows the design of the freezer in the lower part of the refrigerator (namely, a two-temperature home refrigerator). The refrigerator body 1 includes an outer case 2, an inner case 3 located inside the outer case 2, and foam insulation material 4, such as polyurethane foam, which fills the gap between the inner and outer cases 3 and 2. The outer case 2 is made by connecting a plurality of folded steel plates, and the inner casing 3 is made of plastic molding.

The engine room 5 is formed by a concave portion in the lower rear of the refrigerator body 1. In the engine room 5, there is a compressor 6 that implements the refrigeration cycle, and peripheral components (not shown in the drawing). The refrigerator body 1 includes a horizontal bottom 1a and an inclined portion 1b rising back and up with respect to the bottom 1a. The vacuum insulation panel 7 is provided so that it extends from the bottom 1a to the inclined portion 1b. Accordingly, the vacuum insulation panel 7 is generally L-shaped and comprises a horizontal portion 7a and an inclined portion 7b rising back and up with respect to the horizontal portion 7a.

The vacuum insulation panel 7 comprises a core made by forming a heat-insulating mat from a bundle of thin glass fiber or glass wool to shape the mat as described above. The core material is placed in a gas-insulating vessel made of a multilayer film consisting of aluminum foil and synthetic resin and forming a bag. A vacuum is created in the gas-insulating vessel, and its opening is closed so that the interior of the vessel remains in a state of vacuum or rarefied pressure. The vacuum insulation panel 7 is thin and retains low thermal conductivity (i.e., has thermal insulation characteristics).

The horizontal portion 7a of the vacuum insulation panel 7 is attached to the bottom 2a of the outer casing 2 with double-sided adhesive tape (not shown in the drawing) from the bottom 1a of the refrigerator body 1. On the other hand, the heat-insulating mat 8 is attached to the lower part of the inclined surface 2b of the outer casing 2 with double-sided adhesive tape (not shown in the drawing) from the side of the inclined part 1b. The heat-insulating mat 8 contains, for example, foam plastic, which eliminates the need for foam insulating material 4. The heat-insulating mat 8 is so wide as to sufficiently cover the panel 7 from the left edge to the portion of the panel 7 near the right edge, at the lower side of the inclined surface 2b of the outer casing 2 (FIG. 2). In addition, the heat-insulating mat 8 is thicker, as shown in FIG.

In addition, as shown in FIGS. 2 and 3, the inclined part 1b of the refrigerator body 1 has a convex part 9, which is designed in such a way that it corresponds in shape to the aforementioned section of the panel 7 near the right edge of the panel 7 and, therefore, to the compressor 6. The convex part 9 protrudes in a direction opposite to that of engine room 5. As shown in FIGS. 3 and 4, the heat-insulating mat 8 includes a portion 8a located on the side of the convex part 9, and more specifically, performed on a portion on the side of the convex part 9 and continuing into m the vault compartment 5, mating in shape with the convex part 9. In view of formability, it is desirable that the mat portion 8a corresponding in shape to the convex part 9 has an end depth (thickness) × (see FIG. 3) of 5 mm or more.

The inclined portion 7b of the vacuum insulation panel 7 is attached to the heat-insulating mat 8, for example, with double-sided adhesive tape (not shown in the drawing). As shown in FIG. 1, the heat-insulating mat 8 includes a part filling the lower gap between the panel 7 and the inclined portion 2 from the side of the inclined part 1b, without the need for introducing foam insulation material.

The inclined surface 2b of the outer casing 2 comprises a plurality of ventilation holes 10 located around the panel 7 (left, right and top), as shown in FIG. In addition, in order to avoid damage to the panel due to burrs, the ventilation holes are first made from the side of the panel 7, so that the burrs are in the opposite direction to the panel 7. In addition, as shown in FIG. 1, on the back of the bottom of the outer casing 2 made bevel 11 with the back bent upward. As a result, the protruding part of the vacuum insulation panel 7 will be retained even when it breaks down and will not reach the mounting surface of the refrigerator.

FIG. 1 illustrates a freezer 12 surrounded by a bottom 1a, an inclined portion 1b, a rear side 1c and two sides 1d of a refrigerator body 1. Two storage containers 13 and 14 are located above and below inside the freezer 12, so that they can be pulled out separately. In addition, two doors 15 and 16 are mounted on containers 13 and 14 to open and close the upper and lower compartments of the freezer 12, respectively.

In addition, behind the inner part of the freezer 12 is a protective partition 17, limiting the cooling compartment 18 (Figure 1). In the cooling compartment 18, there is provided an evaporator 19 (cooler) of the freezer, performing the refrigeration cycle, and a fan 20 of the freezer, which provides air contact in the refrigerator 12 with the evaporator 19 and air circulation through the air inlet (17a) and outlet (17b).

A vacuum insulating panel 7 is attached to the bottom 2a of the outer casing 2 from the bottom 1a of the refrigerator body 1, as described above. In addition, the heat-insulating mat 8 fills the lower gap between the panel 7 and the inclined portion 2 from the side of the inclined part 1b, without the need for introducing foam insulation material. In this case, the vacuum insulating panel 7 is located in the inclined surface 1b of the housing 1 of the refrigerator. In addition, the heat-insulating mat 8 is located between the vacuum insulating panel 7 and the inclined surface 2b of the outer casing 2. The heat-insulating mat 8 fills the lower gap between the vacuum insulating panel 7 and the inclined surface 2b. As a result, the above-described design allows to obtain more desirable thermal insulation characteristics, even without the use of foam insulation material, in the lower part compared to a conventional design in which a vacuum insulation panel is attached to the inclined surface of the outer casing with a plurality of relatively small spacing elements. This allows for satisfactory thermal insulation. In particular, in the freezer 12, it is possible to obtain the required level of thermal insulation from the compressor 6 located in the engine room 5 behind the inclined surface 1b.

In addition, since the heat insulating mat 8 fills the lower gap between the vacuum insulating panel 7 and the inclined surface 2b, the vacuum insulating panel 7 can be firmly fixed in the inclined part 1b. In addition to the above, the heat-insulating mat 8 can simply be located between the vacuum insulating panel 7 and the inclined surface 2b of the outer casing, while being attached or not attached to the vacuum insulating panel 7 and the inclined surface 2b of the outer casing 2. The heat-insulating mat 8 can be attached both to the vacuum insulating panel 7 and to the inclined surface 2b of the outer casing 2.

The inclined surface 2b of the outer casing 2 comprises a plurality of ventilation openings 10 located around the vacuum insulation panel 7. The ventilation openings are used to perform the necessary degassing in the process of filling the gap between the inner and outer casings 3 and 2 with the foam insulation material 4. Therefore, the foam insulation material 4 may in sufficient quantities to be fed into the gap to the very periphery of the vacuum insulation panel 7 while degassing is carried out by means of ventilation holes 10. Accordingly, it is possible to obtain more desirable thermal insulation characteristics of the refrigerator body 1, in particular of the inclined portion 1b.

In addition, the convex part 9 extends in a direction opposite to the engine room 5, and corresponds in shape to the location of the compressor 6 in the engine room. The convex part 9 is located in the inclined part 1b. Section 8a is made on the section of the heat-insulating mat 8, located on the side of the convex part 9, and corresponds in shape to the convex part 9. Therefore, the heat-insulating mat 8 can be located along the convex part 9, and can be part of an inclined surface 2b other than convex part 9. This allows you to obtain more desirable heat-insulating characteristics of the inclined part 1b of the housing 1 of the refrigerator, in particular, more desirable heat-insulating characteristics of the freezer compartment 12 with respect to heat, emit compressor 6. Moreover, the vacuum insulation panel 7 can be more firmly fixed to the inclined surface 1b.

5 and 6 illustrate the second and third embodiments, respectively. Identical or similar details in each of the above embodiments are indicated by the same reference numerals as in the first embodiment, and only differences between the second and third embodiments from the first will be described.

In the second embodiment (FIG. 5), the inner case 3 comprises an inclined surface 3b forming an inclined part 1b of the refrigerator body 1, in front of the engine room. The elastic element 21 is mounted on the convex part 9 of the inclined surface 3b and protrudes toward the vacuum insulation panel 7.

As a result of the application of the above construction, the elastic member 21 can prevent the vacuum insulating panel 7 from being hit by the inclined surface 3b of the inner housing 3, which prevents the insulation panel 7 from breaking. In addition, the elastic element 21 ensures a gap between the vacuum insulating panel 7 and the inclined surface 3b, which provides a duct through which foam material 4 is supplied. In addition, even if the vacuum insulation panel 7 breaks, it is possible to make the resultant e the bulge did not reach the inclined surface 3b of the inner casing 3, whereby the deformation of the inclined surface 3b can be prevented.

In the third embodiment (FIG. 6), the inner case 3 comprises an inclined surface 3b defining an inclined part 1b of the refrigerator body 1 in front of the engine room. In the convex part 9 of the inclined surface 3b, a concave portion is made protruding toward the vacuum insulation panel 7.

As a result of the application of the above construction, the concave portion 31 also ensures that there is a gap between the vacuum insulation panel 7 and the inclined surface 3b, which provides a flow through which the foam material 4 is supplied. In addition, even if the vacuum insulation panel 7 breaks, it is possible to make as a result, the bulge did not reach the inclined surface 3b of the inner casing 3, which prevents deformation of the inclined surface 3b.

The above description and the accompanying drawings are intended only to illustrate the principles of the invention and should not be construed as limiting. Various changes and modifications are obvious to a person skilled in the art having the usual qualifications. All such changes and modifications are within the scope of the invention defined in the attached claims.

Claims (5)

1. Refrigerator containing:
a refrigerator casing formed by an outer casing, an inner casing housed inside the outer casing, and foam insulation material that fills the gap between the inner and outer casing;
engine room formed in the rear lower part of the refrigerator; and
a vacuum insulating panel provided in the gap between the inner and outer bodies in front of the engine room and continuing along the bottom of the refrigerator body and further along the inclined portion of the refrigerator body forming the engine room;
moreover, a vacuum insulating panel is attached to the bottom of the outer case from the bottom of the refrigerator body,
the vacuum insulation panel extends from the side of the inclined portion of the refrigerator body, while a heat-insulating mat is laid between the inclined portion of the outer case and the vacuum insulation panel, and
the heat-insulating mat includes a part filling the lower gap without introducing foam insulating material. 2. The refrigerator according to claim 1, in which the inclined portion of the outer casing comprises a plurality of ventilation holes located around the vacuum insulation panel. 3. The refrigerator according to claim 1, in which the inclined part of the body is made with a convex part located so as to correspond in shape to the compressor provided in the engine room and carrying out the refrigeration cycle, and protruding in the direction opposite to the engine room, and the heat-insulating mat includes a part located at the convex part and having a corresponding shape. 4. The refrigerator according to claim 1, in which the inner casing comprises an inclined surface forming an inclined part of the refrigerator casing, and the inclined surface of the inner casing is provided with an elastic element protruding towards the vacuum insulation panel. 5. The refrigerator according to claim 1, in which the inner casing comprises an inclined surface forming an inclined part of the refrigerator casing, and the inclined surface of the inner casing is provided with a concave portion protruding towards the vacuum insulation panel.

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