EP1470376A1

EP1470376A1 - Inner wall for a refrigerator housing

Info

Publication number: EP1470376A1
Application number: EP03704445A
Authority: EP
Inventors: Harald Krauss
Original assignee: BSH Bosch und Siemens Hausgeraete GmbH
Current assignee: BSH Hausgeraete GmbH
Priority date: 2002-01-23
Filing date: 2003-01-21
Publication date: 2004-10-27
Also published as: PL369623A1; DE10202494A1; WO2003062721A1; BR0307014A; CN1620586A; WO2003062721A8; RU2004122625A

Abstract

Disclosed is an inner wall (11) for a refrigerator housing, comprising a vertical wall (12) and a ceiling (17) connected to each other by a bent transition segment (18), an opening (13) cut into the vertical wall (12), and an air passage nozzle (14) embedded in the opening in a foam-tight manner. The opening (13) extends through the transition segment (18) to the ceiling (17).

Description

Inner wall for a refrigerator housing

The present invention relates to an inner wall for the housing of a refrigerator, in particular a Nofrost refrigerator.

The housing of a refrigeration device is conventionally constructed from an outer wall and an inner wall, which together delimit an intermediate space filled with insulating foam. In Nofrost refrigeration devices, the evaporator, which is used to cool the interior of the refrigeration device, is housed in a thermally insulated manner from the interior, and the cooling takes place by circulating air between the interior and the chamber of the evaporator.

For the air exchange between the interior and the chamber, a supply opening for the cold air in an upper area of the inner wall and a suction opening in a lower area are required. An air duct connection opening at the supply opening must be fastened close to the inner wall so that no foam can penetrate into the interior when the space is foamed. 1 and 2 show a conventional inner wall 1 with a feed opening 3 in the rear wall 2 and an air duct 4, once in a perspective view and once in a detail section. The air passage socket 4 carries an annular, all-round brim 5, which, as shown in FIG. 2, fits tightly against the rear wall 6 after installation of the air passage socket and thus prevents the passage of foam.

The inner wall is conventionally produced by deep drawing a piece of plastic flat material. In order to avoid that the flat material tears open along the edges of the deep-drawing die with this technique, these edges must be rounded. Therefore, all walls of the inner wall are connected by curved transition sections 8. These transition sections conventionally have a radius of curvature of 10 mm or more.

These transition sections 8 force the opening 3 for the air duct 4 to be made at a distance from the upper wall 7, because on the one hand the opening would be difficult to seal when it enters the transition area intervening between the rear wall 6 and the upper wall 7, on the other hand, the attachment of a fan (not shown) in the interior in front of the opening would be difficult if the surroundings of the opening were not flat.

The fan arranged in front of the opening takes up space in the interior, as a result of which storage space for refrigerated goods is lost in the interior. Shelves can only be placed below the fan, which further undesirably limits the storage options in the interior. Although it would be conceivable to provide a shelf with a cutout adapted to the shape of the fan housing, its production would be disproportionately complex and it could only be used sensibly at the height of the fan housing.

The object of the present invention is to provide an inner wall for a refrigeration device, which allows the supply of an air flow at any height of a side wall up to and including immediately below the top wall. In particular, such an inner wall should make it possible to mount a fan directly below the upper wall in a space-saving manner.

The object is achieved by an inner wall with the features of claim 1.

By enlarging the opening into which the bushing is inserted in a foam-tight manner through the entire transition section up to the upper wall, a passage surface of the bushing can be placed at any height up to and including immediately below the upper wall.

The passage surface is preferably formed in a vertical wall section of the bushing, which extends to the height of the curved transition section. While in the conventional inner wall of FIG. 1, a fan housing arranged on the inside of the inner wall in front of the air passage area must maintain a distance from the upper wall corresponding to the height of the transition section, this is no longer the case with the construction according to the invention. On the one hand, this allows a better use of space in the interior of the refrigerator, since there is no dead volume between the top of the fan housing and the upper wall, and a upper shelf in the refrigerator due to the elimination of this dead volume at a reduced distance from the upper wall, which gives more flexible storage options in the refrigerator.

The vertical wall section and an upper wall section of the ventilation bushing are preferably connected by a sharp corner. In contrast to the actual inner wall, this is possible without difficulty in the case of the air feedthrough connector, since the air feedthrough connector will generally be an injection molded part which is less subject to restrictions in terms of its shape than a deep-drawn part.

The air passage surface is expediently surrounded on the inside of the inner wall by a flat surface over its entire circumference. This flat surface facilitates the installation of a fan. It can be designed entirely on the air duct or in one region on the vertical wall of the inner wall and in another region on the air duct. The former alternative allows a fan to be mounted on the air duct before it is fitted in the opening in the inner wall. In the second alternative, the fan, by being attached to both of the above-mentioned areas, can contribute to the firm connection of the air duct connection to the inner wall.

In order to achieve a foam-tight connection between the air feedthrough and the inner wall at the height of the upper wall, the air feedthrough there is preferably connected to the wall by a tongue and groove connection. Such a tongue and groove connection can be most easily created when an edge of the upper wall forms the tongue and the groove is formed on the air duct.

Further features and advantages of the invention result from the following description of exemplary embodiments with reference to the attached figures. Show it: Figure 1, already treated, a perspective view of a conventional inner wall of a refrigerator;

Figure 2 shows a section through the inner wall of Figure 1 in the plane designated ll-ll;

Figure 3 is a perspective view of the upper region of an inner wall of a refrigerator according to the invention;

Figure 4 shows a section through the inner wall of Figure 3 along the plane designated IV-IV;

Figure 5 is a front view of the inner wall shown in Figures 3 and 4; and

Figure 6 is a front view analogous to Figure 5 of a modified inner wall.

FIG. 3 shows a perspective view of the inner wall 11 according to the invention, from which, as in FIG. 1, the air duct 14 is shown offset for the sake of clarity of illustration. The inner wall 11, formed in one piece by deep drawing from a piece of plastic flat material, has vertical walls, namely a rear wall 12 and side walls 16 and an upper wall 17, which are each connected by rounded transition sections 18. An opening 13 punched into the inner wall 11 has a horizontal upper edge 19 adjoining the upper wall 17, two side edges 20 running in planes parallel to the side walls 16, and a lower edge 21 in the form of an arc of a circle surrounded by straight lines.

The air passage stub 14 provided for foam-tight insertion into the opening 13 has a vertical wall section 22 which collides with a horizontal upper wall section 23 to form a sharp corner. Both wall sections 22, 23 are surrounded by a coherent, circumferential brim 24 which is curved in a quarter circle in its lateral sections in accordance with the shape of the transition section 18. FIG. 4 shows a section through the air duct 14 and the area of the inner wall 11 surrounding it along the lines IV-IV from FIG limited. An angled connection 27 of the pipe section is provided in order to be connected to an evaporator chamber of the refrigeration device. The section of the pipe section 25 which extends into the interior of the refrigeration device serves as a stop for the positioning of a fan 28 which is provided in order to be positioned on the rear wall 12 in such a way that the section of the pipe section 25 which projects into the interior has a free cross section of the fan 28 engages and the top of the fan housing abuts the horizontal wall portion 23.

A flat surface surrounding the air passage opening 26 and the pipe section 25, to which the frame of the fan 28 can be fastened, is formed in a lower region 29 by the rear wall 12 and in an upper region 30 by the vertical wall section 22 of the air bushing 14. This can also be seen in the front view of the inner wall 11 shown in FIG. 5. A dashed line here shows the course of the brim 24 of the air bushing 14 lying on the outside of the inner wall 11.

A groove 31 formed at the front edge of the upper wall section 23 receives the edge 19 of the upper wall 17 and thus ensures a tight and secure hold of the air duct connection at this point.

In the embodiment described above with reference to FIGS. 1 to 5, when installing a refrigeration device, the air duct 14 is first guided from the rear against the inner wall 11 and inserted into the opening 13. The fan 28 is then mounted in the interior of the refrigerator in front of the air passage opening 26. Alternatively, a configuration shown in FIG. 6 in a front view is also possible, in which the opening 13 is enlarged downwards in comparison to the configuration described above, so that the edge of the rear wall 12 does not extend directly to the pipe section 25 and instead the vertical wall section 22 surrounds the air passage opening 26 over its entire circumference. This variant allows a fan to be mounted on the air duct 14 and, if necessary, also lead electrical supply lines of this fan through openings (not shown) of the nozzle before it is mounted in the opening of the inner wall 11. Since operations in the relatively inaccessible interior of the refrigerator are avoided in this way, assembly is simplified in this way.

Claims

claims

1. inner wall (11) for a refrigerator housing, with a vertical wall (12) and an upper wall (17), which are connected to one another by a curved transition section (18), an opening (13) cut into the vertical wall (12) and a bushing (14) inserted into the opening (13) in a foam-tight manner, characterized in that the opening (13) extends through the transition section (18) to the upper wall (17).

2. Inner wall according to claim 1, characterized in that in a vertical wall section (22) of the bushing (14) formed passage surface (26) extends to the height of the curved transition section (18).

3. Inner wall according to claim 1 or 2, characterized in that the vertical wall section (22) and an upper wall section (23) of the bushing (14) are connected by a sharp corner.

4. Inner wall according to one of claims 1 to 3, characterized in that the bushing is designed as an air bushing (14) and the passage surface as an air passage surface (26).

5. Inner wall according to one of claims 1 to 4, characterized in that a plane surface (29, 30) is formed on the inside of the inner wall, which

Air passage surface (26) surrounds on its entire circumference.

6. Inner wall according to claim 5, characterized in that the flat surface (29, 30) in a lower region (29) through the vertical wall (12) and in an upper region (30) through the vertical wall section (22) of the

Air bushing (14) is formed.

7. inner wall according to claim 5, characterized in that the plane surface is formed entirely by the vertical wall portion (22).

8. Inner wall according to one of claims 4 to 6, characterized in that a fan (28) is mounted on the plane surface (29, 30).

9. Inner wall according to one of the preceding claims, characterized in that the air duct (14) with the upper wall (17) is connected by a tongue and groove connection (19, 31)

10. Inner wall according to claim 9, characterized in that the spring is formed by an edge (19) of the upper wall (17) and the groove (31) on the air duct (14).