EP2010837A2

EP2010837A2 - Refrigerator comprising a condensate discharge system

Info

Publication number: EP2010837A2
Application number: EP07727663A
Authority: EP
Inventors: Martin Eichler; Rudolf Schmidt
Original assignee: BSH Bosch und Siemens Hausgeraete GmbH
Current assignee: BSH Hausgeraete GmbH
Priority date: 2006-04-20
Filing date: 2007-04-02
Publication date: 2009-01-07
Also published as: WO2007122073A2; CN101432585A; WO2007122073A3; DE102006018423A1

Abstract

The invention relates to a refrigerator comprising a condensate discharge system, by means of which the condensate is conducted from the interior of the refrigerator towards the outside via a condensate tube and a syphon. According to the invention, the syphon is connected to the condensate tube via a snap-in joint.

Description

Refrigerating appliance with a condensate drainage system

The invention relates to a refrigerator with a condensate drainage system according to the preamble of claim 1.

In refrigerators, especially in No Frost refrigerators and freezers, usually a condensate drainage system is provided, with which the resulting condensate in the interior of the cooling container is passed through a siphon to the outside and there supplied to an evaporation tray. The condensate is usually removed in a corrugated hose. The siphon is often formed by a loop of the corrugated hose of the condensate drainage system.

It has been found that in the siphon algae growth is very fast and closes the siphon. The condensate then accumulates above the siphon and can no longer run into the evaporation tray. In this case, usually the complete condensate drainage system has to be replaced. This is particularly difficult if the siphon is installed in the insulating foam of the refrigerator.

The invention has the object of providing a refrigeration device in such a way that the siphon can be easily replaced when it is closed by algae growth. Furthermore, an early closing of the siphon should be prevented.

The object is achieved according to the invention by a refrigeration device with the features of claim 1. The fact that the siphon is connected via a snap connection with the condensate hose, it can be replaced without the entire condensate drain system must be replaced. A siphon can therefore be replaced without high costs. The pressure applied to the snap connection water pressure is so low that the tightness of the snap connection is readily sufficient. When replacing the siphon therefore no additional sealing work must be performed. The algae growth in the siphon is promoted in particular by light and heat. It is therefore important to keep these influences away from the siphon. According to the invention, the siphon is therefore housed in insulating foam of the refrigerator.

In contrast to a housing of the siphon in the engine compartment of the refrigerator can be significantly lower by these measures, the temperature of the condensate in the siphon. Also, compared to a housing of the siphon on the rear wall of the refrigerator, the temperature of the condensate can be lowered, since the heat from the engine compartment rises and rephrase the siphon attached to the back wall and would also heat up. In the insulating foam of the refrigerator, however, the temperature of the siphon is not appreciably above the temperature of the effluent from the cooling tank condensate.

Also, it is completely dark neither in the engine compartment open to the outside nor on the rear wall of the refrigerator. Through the gap between the wall and rear wall of the refrigerator or through the existing ventilation slots in a cover in built-in appliances, which are necessary to dissipate the heat of the engine and to prevent heat build-up behind the refrigerator, always penetrates light to the siphon in the engine compartment or on the back wall before. If, on the other hand, the siphon is housed in the insulating foam of the refrigeration unit, the incidence of light can be almost completely eliminated.

Advantageously, the siphon is mounted at the end of a flexible drain hose. This hose can be easily adapted to the requirements and laid. This laying is usually done before the insulating layer of the refrigerator is foamed.

In a simple embodiment, the siphon is formed by a loop of a flexible hose. However, this loop is not, as in the prior art, part of the condensate hose, which directs the condensate from the interior of the Kühlbehäl- ters to the evaporation tray, but is a separate part, which is connected only via the snap connection with the condensate hose. In this way, even this very simple form of a siphon can easily be exchanged if excessive algae growth should close the siphon. In another embodiment of the invention, the siphon is designed as an insert. This siphon insert is simple and extremely inexpensive to produce. It can be designed with smooth inner walls. Corners and edges at the necessary deflections can be replaced by curves. In this way, the algae have less attack surfaces, so that algae are at least partially transported with the condensate to the outside.

Particularly advantageously, the siphon is provided in a hollow chamber. If the siphon is used as an insert part, simply the condensate hose, which directs the condensate from the interior of the cooling tank to the siphon, can be extended. In this extension of the siphon insert is inserted from below and fastened via the snap connection.

If the siphon is designed as a loop of a flexible hose, a plastic cloth is provided, into which the condensate hose opens. The loop siphon is then snapped in the downwardly open Kunsstoffglocke directly to the end of the condensate hose.

In both cases, the condensate drain system can be installed before foaming the insulation layer. It only has to be prevented that the insulating foam penetrates into the downwardly open hollow chamber and closes its accessibility. The siphon can then be mounted after foaming and easily replaced at any time in the event of blockage.

In order to be able to reduce the growth of algae even more, the material of the siphon is mixed with additives that inhibit algae growth. As an example, additives based on silver or copper can be mentioned here. Both materials not only work against algae but also against bacterial growth.

Further details and advantages of the invention will become apparent from the subclaims in connection with the description of an embodiment which is explained in detail with reference to the drawing. It shows:

Fig. 1 shows a siphon as a loop of a flexible hose Fig. 2 shows a siphon with exchangeable insert and Fig. 3 shows a detail of the Ringschnappverbindung.

In Fig. 1, the simplest embodiment of a replaceable siphon is shown. The condensate hose 2, which dissipates the condensate from the interior of the cooling tank, is laid in the insulating foam 1 of the refrigerating appliance. It opens into a cavity formed by the plastic lure 14 in the insulating foam 1. A flexible hose with the condensate hose 2 is connected via a sleeve 3 with a ring snap connection. With the help of the plastic bands 4 this is shaped to the siphon 5. From the siphon 5, the condensate is further led via the drain 6 to a Verdungsschale not shown here.

The siphon 5 is thus surrounded by the insulating foam 1 and thereby protected against the heat of the engine and from the light. The condensate in the siphon 5 is therefore kept at a low temperature. As algae growth increases with increasing temperature and brightness, the conditions prevailing here are responsible for low algal growth.

But if the siphon 5 clogged by algae growth, it can be easily replaced. For this purpose, the Ringschnappverbindung the sleeve 3 is released by removing the flexible hose and this removed from below from the cavity. Just as easily, a new flexible hose, which is also formed by bands to a siphon 5, be reinstated. The flexible hose is then connected by insertion into the sleeve 3 by the annular snap connection again with the condensate hose 2.

Fig. 2 shows another embodiment of the invention. Here the condensate hose 2a is expanded. Through this extension 10 creates a cavity 8 in which the siphon insert 9 is inserted. About the ring snap connection 7 of the siphon insert 9 is tightly connected to the extension 10. An additional seal is not required. The condensate passes from the condensate hose 2a into the cavity 8, which is bounded on the outside by the extension 10 and inside by the siphon insert 9. In the siphon insert 9, the condensate rises again and then runs through the drain 6 in an evaporation tray.

The annular snap connection 7 is explained in more detail in FIG. At the connecting flange 1 1, an annular locking and sealing rib 12 is provided. This locking and sealing rib 12 is formed directly on the siphon insert 9. In the extension 10 of the condensate hose 2a a corresponding annular locking groove 13 is impressed. When inserting the siphon insert 9, the end of the extension 10 slides over the locking and sealing rib 12. To facilitate insertion, the end of the extension 10 can be widened again slightly funnel-shaped. The latching and sealing rib 12 then snaps into the annular latching groove 13. This compound is sufficient to create a tightness that does not leak condensate. The seal only has to withstand the pressure of a water column that does not even reach the height of the siphon insert 9.

Again, a simple change of the siphon is possible. It only has to be solved the ring snap connection 7 by pulling down the siphon insert. The clogged siphon insert can then be pulled down and a new siphon 9 inserted into it. By light pressure the Ringschnappverbindung 7 is closed again.

In order to reduce the growth of algae even more, additives can be added to the material of the siphon in both embodiments, which act against algae and bacteria. Such additives include, for example, copper or silver. LIST OF REFERENCE NUMBERS

1 insulating foam

2 condensate drain hose 3 sleeve

4 plastic bands

5 Siphon 6 Evacuation tray drain

7 Ring snap connection 8 cavity

9 Siphon insert 10 Extension of the condensate drain hose

1 1 connection flange

12 locking and sealing rib 13 locking groove

14 Cocoa curl

Claims

claims

1 . Refrigerating appliance with a condensate drainage system, with which the condensate is passed through a condensate hose and a siphon from the inside of the refrigerator to the outside, characterized in that the siphon is releasably connected to the condensate hose.

2. Refrigerating appliance according to claim 1, characterized in that the releasable connection is designed as a frictional and / or positive connection.

3. Refrigerating appliance according to claim 1 or 2, characterized in that the releasable connection is designed as a latching connection.

4. Refrigerating appliance with a condensate drainage system according to claim 1, characterized in that the siphon is arranged in the insulating foam of the refrigerating appliance.

5. Refrigerating appliance with a condensate drainage system according to claim 1 or 4, characterized in that the siphon is mounted at the end of a flexible condensate hose.

6. Refrigerating appliance with a condensate drainage system according to one of claims 1, 4 or 5, characterized in that the siphon through a loop of a flexible

Hose is formed.

7. Refrigerating appliance with a condensate drainage system according to one of claims 1, 4, 5 or 6, characterized in that the siphon is arranged in a hollow chamber.

8. Refrigerating appliance with a condensate drainage system according to one of claims 1, 4, 5, 6 or 7, characterized in that the siphon is designed as an insert part. Refrigerating appliance with a condensate drainage system according to any one of claims 1,4,5,6,7 or 8, characterized in that the material of the siphon is mixed with additives against algae and bacterial growth.