This invention relates to a refrigerating appliance with a collecting or evaporation receptacle for condensed water. A refrigerating appliance is disclosed in DE 198 55 504 A1. This refrigerating appliance of prior art has a heat insulating housing which encloses a storage compartment for goods to be refrigerated and has, in a lower corner, a recess open towards the outside in which a compressor is installed for a refrigerant circuit of the refrigerating appliance. A collecting receptacle is mounted on the compressor housing for condensed water which condenses in the storage compartment and flows out through an opening formed above the collecting receptacle in the housing into the collecting receptacle.
The collecting receptacle is mounted on the compressor housing in order to utilise loss heat which the compressor generates during operation, and to heat the condensed water in the collecting receptacle, thereby accelerating its evaporation.
In recent years considerable efforts have been made to reduce the energy consumption of refrigerating appliances, as a result of which the power input which the compressor must have in order to cool the storage compartment effectively is being increasingly reduced with advanced development. In modern refrigerating appliances with high quality insulation it may therefore happen that the waste heat from the compressor is no longer sufficient to evaporate the condensed water at the rate at which it flows out of the storage compartment, so that the collecting receptacle eventually overflows. If the overflowing condensed water reaches live parts below the drip tray, damage to the electrics of the refrigerating appliance may result. Condensed water escaping from the appliance may also lead to damage elsewhere, particularly in the case of built-in appliances which are provided for installation in kitchen cabinets. Problems of this kind may arise, particularly in the case of self-defrosting appliances in which the condensed water is produced in pulses in large quantities.
The object of this invention is to provide a refrigerating appliance in which overflowing of the collecting tray can be reliably avoided, even if waste heat discharged from the compressor to the drip tray is low.
The object is achieved by a refrigerating appliance with the features of the claims. The heating power supplied to the collecting tray can be supplemented by means of the independent heating device to the extent required to prevent overflowing.
The heating device is preferably formed essentially by an ohmic resistance.
The heating device can be arranged simply on a wall of the collecting receptacle; in order to introduce the thermal energy discharged by it into the condensed water contained in the collecting receptacle with the lowest possible loss, the heating device is preferably arranged so that it is immersed in the collecting receptacle.
A control circuit may be provided for operating the heating device periodically. If the ratio of the operating time of the heating device to the total operating time of the refrigerating appliance can be adjusted on the control circuit, the mean heating power may always be limited to the minimum required to prevent overflow, according to the climatic conditions under which the refrigerating appliance is used.
According to a preferred embodiment a door opening sensor is provided on a door of the refrigerating appliance, and a control circuit connected to the door opening sensor controls the average power of the heating device according to the frequency of the recorded door openings. This embodiment is based on the consideration that a certain quantity of moisture is introduced into the refrigerating appliance whenever the door is opened due to the air exchange between the storage compartment of the refrigerating appliance and its surroundings, and that this moisture eventually reaches the collecting receptacle as condensed water, and must be evaporated from it so that the heat energy required for this must be supplied.
According to a particularly economic embodiment a water level sensor is arranged on the collecting receptacle and a control circuit connected to the water level sensor operates the heating device if the water level recorded by the water level sensor exceeds a limit value. In this embodiment heat energy is actually only expended when this is required to prevent overflow; here there are no safety margins which are required in the case of purely time-controlled operation of the heating device or operation of the heating device controlled on the basis of the frequency of the door openings in order to allow for fluctuations in the climatic conditions or the emission of moisture by goods to be refrigerated and stored in the refrigerating appliance.
The water level sensor is preferably formed by a float switch.
Further features and advantages of the invention are explained in the following description of exemplary embodiments, with reference to the attached figures, where:
The refrigerating appliance shown diagrammatically in
Air moisture from interior space 3, which condenses on its wall cooled by evaporator 5, is accumulated on the lower edge of this wall in a gutter 10 and is fed from there via a drain pipe 11 guided through foam filling 6 to a bowl-shaped collecting receptacle 12, which is mounted on compressor 7 in order to be heated by its waste heat.
The air moisture produced by evaporation from collecting receptacle 12 in recess 9 is flushed away by an air flow which, driven by the heat discharged by liquefier 8 in a flue between the rear wall of body 1 and an opposing cabinet or building wall, not shown, runs firstly through an intake duct 30 guided along the bottom of body 1, then through recess 9 and finally via the flue and into the open air.
By inserting upper housing section 14 directly into bottom 13 it is possible, as shown in
An electrically operating heating rod 17 is immersed from above into collecting receptacle 12, and extends in it in the form of a loop. It is supplied with energy by a control circuit 18 (see
According to a simple embodiment control circuit 18 comprises a timer, which switches heating rod 17 on and off for a fixed period. The proportion of the connection time of each period may in the simplest case also be fixed, since in the case of a refrigerator used in a hot environment, the quantity of liquid which is introduced into storage compartment 3 whenever the door is opened, and which must ultimately be evaporated in collecting receptacle 12, is indeed greater than in the case of a refrigerator used in a cold environment. At the same time, however, the proportion of the compressor running time of the total operating time of the refrigerator is also higher in a hot environment than in a cold one, with the result that more waste heat from compressor 7 is also available for evaporation. However, the length of operating phases 17 may also be adjusted on control circuit 18 to take account of the influence of the ambient climate, or other ambient factors that vary from one appliance to another, on the condensed water produced.
According to a second further developed embodiment a door opening sensor 19 is connected to control circuit 18. This sensor may, for example, be a magnetic field sensor subjected to the magnetic field of a magnetic seal of door 2, or simply a switch which is normally provided on each refrigerating appliance for switching the interior lighting of storage compartment 3 on and off, depending on the opening condition of door 2. Control circuit 18 counts the door opening processes recorded by this door opening sensor 19 and switches on heating rod 17 after a predetermined number of recorded door openings for a predetermined period of time which is preset by the manufacturer so that the waste heat from compressor 7, together with the quantity of heat given off by heating rod 17, would have to be sufficient to evaporate an estimated quantity of moisture introduced by the door openings.
In a third further developed embodiment sensor circuit 18 is instead connected to a door opening sensor with a water level sensor 20 fitted on collecting receptacle 12.
A temperature sensor 26 fitted to the inside of collecting receptacle 12, in the vicinity of heating wire 25, here serves as a sensor for the water level in collecting receptacle 12. When the heating wire is in operation the temperature recorded by temperature sensor 26 depends on whether it, and regions of heating resistance 25 adjacent to it, lie below the water level or not. If the temperature recorded by this sensor 26 during the operation of heating wire 25 exceeds an empirically established limit value, it may be concluded from this that these regions of heating wire 25 adjacent to temperature sensor 26 are not immersed in the condensed water, and that consequently it is not necessary to operate heating wire 25. In other words, in this embodiment a control circuit 18 connected to temperature sensor 26 can, from time to time, put heating wire 25 into operation for test purposes in order to evaluate the resistance in collecting receptacle 12 on the basis of the heating of temperature sensor 26, and if the evaluation indicates that the water level is not critical, the operation of heating wire 25 is interrupted again immediately. Otherwise its operation is continued, if necessary with an output that is higher than in the preceding test phase, until the water level has dropped below a critical value and this is reflected in a rise in the temperature recorded by sensor 26.
Such a temperature sensor 26 could also be secured directly to heating rod 17 in the embodiment shown in
Number | Date | Country | Kind |
---|---|---|---|
10 2004 012 498 | Mar 2004 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2005/051136 | 3/14/2005 | WO | 00 | 6/25/2008 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2005/090878 | 9/29/2005 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2315222 | Philipp | Mar 1943 | A |
5545878 | Jasper, II et al. | Aug 1996 | A |
Number | Date | Country |
---|---|---|
198 55 504 | Jun 2000 | DE |
102 08 558 | Sep 2003 | DE |
08035757 | Feb 1996 | JP |
8 271120 | Oct 1996 | JP |
08271120 | Oct 1996 | JP |
2003 130535 | May 2003 | JP |
2003 279229 | Oct 2003 | JP |
Number | Date | Country | |
---|---|---|---|
20080250799 A1 | Oct 2008 | US |