WO2008025630A1

WO2008025630A1 - Device for evaporating defrosting water collected in a collecting tray of a refrigerator und refrigerator comprising said device

Info

Publication number: WO2008025630A1
Application number: PCT/EP2007/057931
Authority: WO
Inventors: Kasim Yazan
Original assignee: BSH Bosch und Siemens Hausgeräte GmbH
Priority date: 2006-08-29
Filing date: 2007-08-01
Publication date: 2008-03-06
Also published as: EP2059742A1; RU2009105039A; DE102006040378A1; RU2429431C2

Abstract

The invention relates to device for evaporating defrosting water collected in a collecting tray (12) of a refrigerator (1) provided with refrigerant, the refrigerator comprising a refrigerant compressor (3), an evaporator (2) and a refrigerant pipe arrangement (4, 5) connecting the evaporator and the refrigerant compressor (3). The collected defrosting water is fed by means of a capillary guiding device (13; 15) from the respective collecting tray (12) to a heated location of the refrigerator (1) directly on the top of the refrigerant compressor (3) and/or to a condenser region (4) of the refrigerant pipe arrangement (4, 5) emitting heat.

Description

Device for evaporating defrosting water and cooling device collected in a collector of a refrigerator with such a device

The present invention relates to an apparatus for evaporating defrosting water collected in a collecting tray of a refrigerant compressor, an evaporator and a refrigerant piping connecting same and the refrigerant compressor by passing the respective defrosting water from the respective collecting tray by means of a water guiding device using a capillary effect to a heated location of the refrigerator; The invention further relates to a cooling device with such a device.

It is already known to exploit the waste heat of the existing compressor to evaporate the defrost water collected by a refrigerator operating according to the compression principle outside the cooling region (Japanese Patent 2 213 682). For this purpose, the defrosting water is collected in a collecting tank arranged above the relevant compressor, from which then the defrosting water passes through a pipeline arrangement taking advantage of the capillary effect to a plate having openings on the top side of the collecting container. Through the openings of said plate then flows from the compressor to the reservoir high-rising heat and thus evaporates the defrost water, which has accumulated on said plate. However, this type of evaporation of defrost water has proven to be insufficient because often not so much water can be evaporated as recorded by the sump. Sometimes it can therefore come to an overflow of the collecting container by the defrosting water received by this.

In order to alleviate the above-mentioned problem, it has also been attempted to increase the evaporation amount of defrosting water collected outside a refrigerator operating on the principle of compression by utilizing the waste heat of a compressor of the refrigerator in question (Japanese Patent 4 126 977). in that defrosting water contained in a defrosting water collecting arrangement is passed by capillary action to an evaporation part to which the waste heat discharged from the compressor by means of a separate blowing device is supplied. However, the resulting evaporation of the defrosting water delivered by the refrigerator has also often proved insufficient. grasslands. In addition, the generation of noise caused by the aforementioned fan device is considered undesirable.

In a very similar device (Japanese Patent 3 177 775) has been tried as the last considered known refrigerator, the efficiency in the evaporation of water, which is caused by defrosting to increase in the following manner. The defrost water collected in a receptacle is sucked by evaporation bodies utilizing the capillary effect and evaporated on the surfaces of the respective evaporation body by blowing a heated by a blower device and heated by the waste heat from an associated compressor air flow between the respective evaporation body. Thus, warm air is blown through the blower device against the aforementioned evaporation body here, too. As a result, there are also the same drawbacks that have been mentioned in connection with the previously considered known refrigerator for increasing the evaporation rate of defrost water.

The invention is therefore based on the object to show a way, as in a device and a cooling device of the type mentioned in a particularly simple manner compared to the evaporation of defrosting water achieved in the previously known cooling devices more efficient evaporation of defrost water, which supplied by a refrigerator is, can be achieved.

The aforementioned object is achieved in a device of the type mentioned in the present invention in that the heated point of the cooling device is located directly on the top of the refrigerant compressor and / or in a heat-releasing condenser region of the refrigerant line arrangement.

The invention has the advantage that with relatively little design effort compared to the previously known devices more effective evaporation of defrost water is achieved in a refrigerator.

According to an expedient development of the invention, the refrigerant compressor is surrounded by the collecting tray and provided with capillary guide devices leading out of the region of the relevant collecting tray to the upper side of the refrigerant compressor. This brings with it the advantage that defrosting water located in the collection bowl is particularly simple and effective effective way is passed to the most heated area of the refrigerant compressor, resulting in a particularly favorable efficiency in the evaporation of the defrost water.

According to a further expedient development of the invention, at the upper end of the capillary guide devices, a water suction device is applied directly on the upper outer side of the refrigerant compressor. As a result, defrosting water that has not yet evaporated can be sucked up at the upper end of the capillary line devices mentioned in an advantageous manner in order then to be evaporated there and not to return to the collecting bowl on the outside of the respective capillary tube.

According to yet another expedient embodiment of the invention, the capillary guiding devices forming capillary guide elements are mounted on the outside of the refrigerant compressor. This has the advantage that the capillary guide elements can exploit the waste heat of the refrigerant compressor directly.

According to another advantageous embodiment of the invention, the capillary guide devices are formed by the fact that the outside of the refrigerant compressor is surrounded by an outer shell open towards its upper side on the inside thereof in connection with the outside of the refrigerant compressor surrounded by it or with one of these outside absorbable Inner shell, the capillary guide means are formed. Again, there is the advantage that the capillary tube can exploit the waste heat of the refrigerant compressor directly.

Yet another expedient development of the invention consists in that at least one capillary tube which is open on both sides leads from the collection bowl to the heat-emitting liquefier region of the refrigerant line arrangement. This has the advantage that the condenser region of the refrigerant piping arrangement can also be utilized for evaporation of the defrosting water. Thus, the condenser portion can be exploited in a relatively simple manner, either alone or together with the top of the refrigerant compressor for the evaporation of defrost water.

According to a further advantageous embodiment of the invention, the aforementioned at least one capillary tube in the condenser region of the refrigerant piping arrangement is placed around or connected to a hot, liquid refrigerant leading discharge line. There- by the defrost water is pumped out of the collection tray directly to a particularly effective evaporation point.

According to yet another advantageous embodiment of the invention, the at least one capillary tube in the condenser region of the refrigerant piping arrangement is additionally connected to a water suction device. As a result, the water is advantageously absorbed in the mentioned condenser region of the refrigerant piping arrangement for subsequent evaporation, without returning to the collecting dish on the outside of the respective capillary tube.

With reference to the accompanying drawings, the invention is explained below with reference to exemplary embodiments. In the drawings show

1 is a schematic representation of a cooling device with a device according to a first embodiment of the invention,

Fig. 2 is a schematic representation of a cooling device with a device according to a second embodiment of the invention and

Fig. 3 is a schematic representation of a cooling device with a device according to a third embodiment of the invention.

In Fig. 1 is a schematic illustration of a cooling device 1 is illustrated with a device according to the first embodiment of the present invention. The cooling device 1, which may be a refrigerator or a freezer, comprises in a manner known per se a closed refrigerant circuit, to which an evaporator 2, a refrigerant compressor or compressor 3 and one the evaporator 2 and the refrigerant compressor 3 with each other connecting refrigerant piping arrangement, which includes a leading from the refrigerant compressor 3 to the evaporator 2 discharge line 4 and from the evaporator 2 to the refrigerant compressor 3 recirculating return line 5 includes. In the region of the discharge line 4, the refrigerant contained in the refrigerant circuit is in the hot, liquid state, and in the region of the return line 5, the refrigerant in question is in the cold, gaseous state. The region encompassing the delivery line 4 is also referred to as the condenser region. It should be noted at this point that in Fig. 1, only the principle essential elements of Refrigerant circuit are shown; Other, usually provided in the actual realization of a refrigerator or freezer elements, such as a throttle on the inlet side of the evaporator, are not shown here.

The unsupported in Fig. 1 support rods carrying discharge line 4 is in a conventional manner, an approximately meandering cooling coil, which is arranged on the outer rear side of the refrigerator 1; from this area of the cooling device 1 heat is released by means of the coolant to the outside, which is withdrawn from the interior of the relevant cooling device 1. Also, the refrigerant compressor 3 is arranged on the outside of the refrigerator 1. Within the cooling device 1 - which is the area indicated by a dot-dash line in FIG. 1 - are the evaporator 2 and the end portion of the discharge line 4 and the initial region of the return line 5; In this area, heat is withdrawn by means of returning to the gaseous state refrigerant.

Within the cooling device 1, there are also a temperature selector 6, with which the desired cooling temperature in the cooling unit 1 can be preselected, and a temperature sensor 7, which determines the respective temperature in the cooling device 1. Both the temperature selector 6 and the temperature sensor 7 are connected on the output side to control inputs of a control unit 8, which is connected to a power supply input at a terminal 9 to which a supply voltage for the operation of the refrigerant compressor 3 is supplied, for example, a mains voltage. The control unit 8 takes depending on the setting of the temperature selector 6 and the respective temperature measurement signals supplied by the temperature sensor 7 such a control of the refrigerant compressor 3, that in the refrigerator 1 finally determined by means of the temperature sensor 7 temperature of the temperature selector 6 is turned on - set temperature corresponds.

Within the cooling device 1, a collecting funnel 10 is further indicated in Fig. 1, which serves to collect defrosting water, which forms in the cooling device 1. The collecting funnel 10 will usually be arranged in the rear side of the inner lining of the cooling device 1. From the collecting funnel 10 leads a discharge line 1 1 from the interior of the refrigerator 1 to the outside, namely in accordance with FIG. 1 to a collecting container 12, which surrounds the top of the refrigerant compressor 3. Into this collecting tank 12, the defrost water caught by the collecting funnel 10 flows, and it is heated by the heat discharged from the refrigerant compressor 3 particularly in the upper area thereof and thus evaporated. The evaporation of the defrost water collected in the sump 12 still becomes according to the present invention further increased that at least a portion of the surface of the upper part of the refrigerant compressor 3 is provided with a capillary effect using capillary guiding capillary 13, which further guide the defrosting water contained in the collecting container 12 by utilizing the capillary effect to the top of the refrigerant compressor 3 - and although in the area of the relevant top, which is the warmest area of this top. Thus, the defrost water in question is exposed to an even greater evaporation, since it is even warmer in this upper region of the refrigerant compressor 3 than in the region in which the collecting container 12 is located around the refrigerant compressor 3, and since the defrost water in this upper coolant compressor area with this in very effective direct contact.

The above-explained device with the capillary guide devices 13 can either contain individual capillary guide elements 13 which are mounted directly on the upper outer side of the refrigerant compressor 3, or their capillary guide devices 13 can be formed in that the outside of the refrigerant compressor 3 is surrounded by an outer shell open toward its upper side, on the inside of which the capillary tubes are formed in conjunction with the outer side of the refrigerant compressor 3 surrounded by it, or with an inner casing which can be received from this outer side. In this case, the respective outer shell of the respective outer side of the refrigerant compressor 3 may optionally be removable and, for example, after a successful cleaning again be placed on said outside or replaced by a new corresponding outer shell. However, it is also possible to additionally provide the outer shell in question with an inner shell, between which and the said outer shell, the capillary Leitele- elements are formed. In this case, the device comprising outer shell, capillary guide elements 13 and inner shell is or is then applied to the outside of the refrigerant compressor 3.

In addition to the above-mentioned devices, a water suction device 14 may be provided on the upper side of the refrigerant compressor 3 in the region of the outlet ends of the capillary guide elements 13, which may be formed in particular by a sponge or by a foam part. As a result, defrosting water which has not yet evaporated can be collected at the outlet ends of the capillary guide elements 13 for subsequent evaporation in order not to return to the collecting container 12 on the outside of the capillary guide devices 13.

The cooling device 1 'shown in Fig. 2 with the device according to the second embodiment of the invention is in its basic structure with the structure of that shown in Fig. 1 Cooling unit 1 match. The operation of this second embodiment of the device according to the invention corresponds to the operation of the first embodiment of the device according to the invention. Therefore, the device structure and the operation of the relevant second embodiment of the device according to the invention need not be explained again here. The device according to FIG. 2 differs from the first embodiment of the invention described above with reference to FIG. 1 only in that the heated area of the cooling device 1 is not utilized directly on the upper side of the refrigerant compressor 3, but rather here Place in the heat-emitting condenser region of the refrigerant piping arrangement, which is here the area of the discharge line 4 is utilized. At least one capillary tube 15, open at both ends, leads to this discharge line 4 according to FIG. 2, which is immersed at one end into the collecting container 12, with its other end connected to the delivery line 4 at the attachment point 16, for example by soldering, Welding or masking. This at least one capillary tube 15 here represents the water guide, which is formed according to FIG. 1 by the capillary guide devices or -Leitelemente.

It should also be noted here that in the area of the upper side of the at least one capillary tube 15, a corresponding water suction device may be provided, like the water suction device 14 explained in connection with FIG. 1.

The cooling device 1 "shown in FIG. 3 with the device according to the third embodiment of the invention represents a combination of the two previously described with reference to FIGS. 1 and 2 cooling devices 1 and 1 'with the first and second embodiments of the device according to the invention Thus, according to FIG. 3, the capillary guiding devices or guiding elements 13 present on the upper side of the refrigerant compressor 3 and the at least one capillary tube 15 act together in combination to forward the defrosting water collected in the collecting tray 12 to warmer areas of the cooling device 1 On the one hand, this is the top side of the refrigerant compressor 3, and on the other hand, this is a region of the discharge line 4, preferably in the immediate vicinity of the refrigerant compressor 3. As a result, the device according to FIG. 3 has a higher height than the devices according to FIGS Evaporation efficiency on. After the construction of the refrigerator 1 "according to FIG. 3 corresponds to the cooling devices 1 and 1 'illustrated in FIGS. 1 and 2 and explained above, the description of the construction and the mode of operation of the cooling device 1" need not be repeated here. LIST OF REFERENCE NUMBERS

1 cooling unit

2 evaporators

3 refrigerant compressor

4 delivery line

5 return line

6 temperature selector

7 temperature sensor

8 control unit

9 At the end

10 catching funnels

1 1 discharge line

12 collection containers

13 capillary guiding devices, guiding elements

14 water suction device

15 capillary tubes

16 attachment point

Claims

claims

1. A device for evaporating in a collecting tray of a refrigerant compressor, a vaporizer and this and the refrigerant compressor connecting refrigerant piping for a refrigerant containing cooling device collected defrosting water by forwarding the respective defrosting water from the respective collection shell by means of a capillary effect using water supply to a heated Location of the refrigerating appliance, characterized in that the heated point of the cooling device (1) is located directly on the top of the refrigerant compressor (3) and / or in a heat-releasing condenser region (4) of the refrigerant piping arrangement (4, 5).

2. Device according to claim 1, characterized Porsche Style nzeich net, that the refrigerant compressor (3) of the collecting tray (12) is surrounded and with from the area of the respective collecting tray (12) to the top of the refrigerant compressor (3) hinführenden capillary Leitein- directions (13) is provided.

3. A device according to claim 2, characterized Porsche Style nzeich net, that at the upper end of the capillary guide means (13) a Wasseraufsaugeinrichtung (14) directly on the upper outer side of the refrigerant compressor (3) is mounted.

4. Apparatus according to claim 2 or 3, characterized Porsche Style nzeich net, that the capillary guide means (13) forming capillary guide elements (13) on the outside of the cold center I compressor (3) are mounted.

5. Apparatus according to claim 2 or 3, characterized in that the capillary guide means (13) are formed by the fact that the outside of the refrigerant compressor (3) is surrounded by an outer shell open to the top, on the inside in conjunction with the Surrounded by it outside of the refrigerant compressor (3) or with an accommodatable from this outside inner shell, the capillary guide means (13) are formed.

6. Device according to one of claims 1 to 5, characterized in that from the collecting tray (12) at least one capillary tube (15) open on both sides leads to the heat-emitting condenser region (4) of the refrigerant line arrangement (4, 5).

7. Apparatus according to claim 6, dadu rch in that the at least one capillary tube (15) in the condenser region (4) of the refrigerant piping (4, 5) around a hot, liquid refrigerant leading discharge line (4) wrapped around or connected to this is.

8. Apparatus according to claim 6 or 7, characterized Porsche Style nzeich that the at least one capillary tube (15) in the condenser region of the refrigerant piping (16) is additionally provided with a Wasseraufsaugeinrichtung.

9. Cooling device using a device according to one of claims 1 to 8.