DE102014213808A1 - Domestic refrigerating appliance with an oxygen device for carrying out a water electrolysis in a closed circuit with a filter device - Google Patents

Abstract

The invention relates to a household refrigerating appliance (1) having a storage area (8) for food, and to an oxygen device (11) for adjusting the oxygen in the storage area (8), which has a membrane-electrode arrangement (12) with an anode (16 ) and a cathode (14), wherein a through the oxygen device (11) supported water electrolysis as in the household refrigeration appliance (1) closed circuit (13) is executed and between the cathode (14) and the anode (16) a delivery line (17) is formed, in which by means of a pump (18) at the cathode (14) resulting water to the anode (16) can be conducted, and in the conveying line (17) a filter device (19) for filtering in the closed circuit (13) in Operating occurring particles is arranged.

Description

The invention relates to a domestic refrigerator with a storage area for food, which has an oxygen device for adjusting the oxygen in the storage area. The oxygen device comprises a membrane-electrode assembly having an anode and a cathode as electrodes.

In addition to the temperature in the storage area, other factors are essential for keeping foodstuffs fresh in the storage area. An important factor here is the oxygen content. With a suitable oxygen concentration, bacterial growth can be significantly slowed down. It is known that a very preferred oxygen concentration, depending on the type of food, is about five percent.

In the context, for example, from the JP 2004 293 827 known to produce such an oxygen concentration by means of a water electrolysis. For the operation of the water electrolysis water is used, which is provided at the anode of the membrane-electrode assembly available.

In a water electrolysis, water is split at the membrane-electrode assembly into protons and oxygen. The protons are transported across the membrane of this arrangement and oxygen is excreted into the environment and thus discharged into the interior of the storage area. At the cathode of this membrane-electrode assembly, the protons react with the oxygen of the air in the storage area and water molecules are thereby formed again. These are then deposited at the cathode of the membrane-electrode assembly.

The supply of the system with water can be done by continuous external water supply. In this context, an open system is then formed. In such an open system, the water is consumed and must be removed from the system at the cathode. Moreover, in an open system, it can not be ruled out that particles will detach from the membrane-electrode assembly and thus lead to contamination of the water. This can also lead to damage of the electrodes and thus of the anode and / or the cathode or the membrane and thus affect the efficiency and the life of the oxygen generating device. The provision of high quality water at the anode of the assembly thus also represents an important requirement for the long-term functioning of the system.

In contrast to a closed system and thus a closed circuit, no water is supplied externally.

It is an object of the present invention to provide a household refrigerating appliance in which the oxygen generating apparatus can be operated with clean water for a long time.

This object is achieved by a household refrigerator, which has the features of claim 1.

An inventive household refrigerator includes a storage area for food. In addition, the household refrigerator comprises an oxygen device, which is designed to adjust the oxygen and thus the oxygen content in the storage area. The oxygen device comprises a membrane-electrode assembly having an anode and a cathode as electrodes. The oxygen device operates in particular such that the oxygen in the storage area is set or reduced to a value less than or equal to 10%, in particular less than or equal to 6%.

An essential idea of the invention is to be seen in that an oxygen device is formed, which at least supports a water electrolysis, and the electrolysis of water is carried out as a closed circuit in the domestic refrigerator and between the cathode and the anode, a delivery line is formed. In the delivery line, a water accumulating at the cathode can be conducted to the anode by means of a pump of the household refrigerating appliance. In the delivery line, a filter device for filtering out of particles occurring in the closed circuit during operation is arranged. As a closed circuit with respect to the electrolysis of water, such is referred to, in which the water required for the electrolysis of water by the resulting at the cathode water z. B. is transported by a pump back to the anode. In this case, the water can be stored in front of the anode in a container. The water production is due to chemical and physical processes, as explained in the introduction. Virtually no water is supplied externally in a closed circuit, which then defines this closed circuit. Especially with such a configuration, it is then possible by means of the specifically spatially arranged filter device and with the filter device as such to circulate permanently purified water, so that the functionality of the oxygen generating device is kept permanently high.

Preferably, it is provided that the filter device downstream of the pump in the Delivery line is arranged. This makes it possible that by the arrangement of the filter device between the pump and the anode and possibly also when conveying the water from the pump into the water passing particles can be filtered out by the filter device, which is very advantageous.

It is preferably provided that the filter device has at least one coarse filter. Such a filter is advantageous in that even relatively large particles can be filtered out and thus do not reach the anode.

In an advantageous embodiment, it is provided that the filter device has at least one fine filter. By means of this embodiment, even very small particles can be filtered out of the water. It is preferably provided that the filter device has at least one coarse filter and at least one fine filter. Thereby, the above-mentioned advantages can be combined and the filtering process can be improved compared to a single filter. Because it is thus not a single filter relatively quickly added by the particles and clogged, but by this stepwise filtering of different particle sizes and the flow through the filter as long as possible with sufficient amount of liquid allows. In addition, it can then also be provided that, in the case of a plurality of filters, these filters can be exchanged separately, so that it is also possible to respond as required.

It is preferably provided that the filter device is arranged with at least one filter so that no further functional part is arranged in the conveying line between the filter and the anode. This is a particularly advantageous embodiment, since thus virtually no component is present after the filter device through which particles could get into the water, which then also reach the anode. It is thus achieved that virtually particle-free water passes to the anode, so that the electrolysis of water can be carried out without restriction and beyond the entire oxygen device can be operated long-lived and has a high efficiency.

Further features of the invention will become apparent from the claims, the figures and the description of the figures. The features and feature combinations mentioned above in the description, as well as the features and combinations of features mentioned below in the description of the figures and / or shown alone in the figures, can be used not only in the respectively specified combination but also in other combinations or in isolation, without the frame to leave the invention. Thus, embodiments of the invention are to be regarded as encompassed and disclosed, which are not explicitly shown and explained in the figures, however, emerge and can be produced by separated combinations of features from the embodiments explained.

Embodiments of the invention are explained in more detail below with reference to schematic drawings. Show it:

1 a schematic perspective view of an embodiment of a household refrigerator according to the invention; and

2 a schematic representation of sub-components relating to the oxygen device of the household refrigerator according to 1 ,

In the figures, identical or functionally identical elements are provided with the same reference numerals.

In 1 is in an exemplary representation of a household refrigerator 1 shown, which is designed as a fridge-freezer combination device. However, it may also be designed as a cooling only or freezer only. The household refrigerator 1 is designed to contain food. It includes a body 2 with an inner container 3 , The inner container 3 limited with its walls a first interior which has a refrigerator 4 is, and arranged thereunder, separated second interior, which is a freezer compartment 5 is. The fridge 4 generally serves for frost-free cooling of refrigerated goods, preferably at temperatures between + 4 ° C and + 8 ° C. The refrigerator is with the door open 6 , the front of the fridge 4 closes, accessible. The freezer room 5 is generally used for freezing frozen food, for example at -18 ° C. The freezer room 5 is when the freezer compartment door is open 7 accessible. In the embodiment is in the refrigerator 4 a storage area 8th formed, in the embodiment, a container 10 has, which is designed like a drawer and in the horizontal direction and thus in the z-direction is pulled out and hineinschiebbar. Above this is preferably a lid 9 formed the storage area 8th covers and thus the container 10 covers. The storage area 8th is preferably of the remaining volume of the interior or the cooling space 4 hermetically separated. The storage area 8th can also be designed as a zero-degree compartment, in particular for keeping fruit or vegetables fresh.

The household refrigerator 1 also includes an oxygen device 11 for targeted and defined adjustment of oxygen or oxygen content in the storage area 8th , The oxygen device 11 includes a membrane-electrode assembly 12 , as they are then in 2 is shown by way of example.

In 2 is in a simplified representation of the oxygen device 11 shown, wherein it is shown schematically in corresponding sub-components. As can be seen, the membrane electrode assembly 12 in a closed cycle 13 arranged with respect to the electrolysis of water. The membrane electrode assembly 12 includes an anode 16 , a membrane 15 and a cathode 14 , The anode 16 is with the storage area 8th for introducing generated oxygen into the storage area 8th coupled. In addition, a support line 17 formed, extending between the cathode 14 and the anode 16 extends. In the promotion line 17 is downstream to the cathode 14 a pump 18 arranged in the delivery line 17 circulating water from the cathode 14 to the anode 16 promotes. Upstream of the pump 18 is a filter device 19 in the promotion line 17 arranged. The filter device 19 can have one or more filters. It may preferably comprise at least one coarse filter and at least one fine filter. It is envisaged that between the filter device 19 and the anode 16 no further functional part in the delivery line 17 is arranged. This will do so by the filter device 19 Particles of filtered water on the way to the anode 16 not contaminated.

So far, only the acidic electrolysis with a proton exchange membrane has been considered and described. Basically and advantageously, an alkaline electrolysis is possible, in which case an OH molecule is transported across the membrane.

LIST OF REFERENCE NUMBERS

1

 Household refrigerator

2

 corpus

3

 inner container

4

 refrigerator

5

 freezer

6

 door

7

 Freezer door

8th

 storage area

9

 cover

10

 container

11

 Oxygen generation device

12

 Membrane electrode assembly

13

 circulation

14

 cathode

15

 membrane

16

 anode

17

 delivery line

18

 pump

19

 filtering device

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2004293827 [0003]

Claims (5)

Household refrigeration appliance ( 1 ) with a storage area ( 8th ) for food, and with an oxygen device ( 11 ) for adjusting the oxygen in the storage area ( 8th ), which has a membrane-electrode arrangement ( 12 ) with an anode ( 16 ) and a cathode ( 14 ), characterized in that one through the oxygen device ( 11 ) supported electrolysis of water as domestic refrigeration appliance ( 1 ) closed circle ( 13 ) and between the cathode ( 14 ) and the anode ( 16 ) a support line ( 17 ) is formed, in which by means of a pump ( 18 ) on the cathode ( 14 ) accumulating water to the anode ( 16 ) and in the pipeline ( 17 ) a filter device ( 19 ) for filtering in a closed circuit ( 13 ) is arranged during operation occurring particles. Household refrigeration appliance ( 1 ) according to claim 1, characterized in that the filter device ( 19 ) upstream of the pump ( 18 ) in the support line ( 17 ) is arranged. Household refrigeration appliance ( 1 ) according to claim 1 or 2, characterized in that the filter device ( 19 ) has at least one coarse filter. Household refrigeration appliance ( 1 ) according to one of the preceding claims, characterized in that the filter device ( 19 ) has at least one fine filter. Household refrigeration appliance ( 1 ) according to one of the preceding claims, characterized in that the filter device ( 19 ) is arranged with at least one filter such that between the filter and the anode ( 16 ) no further functional part in the delivery line ( 17 ) is arranged.

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