EP1728031A1

EP1728031A1 - Refrigerating appliance

Info

Publication number: EP1728031A1
Application number: EP05717022A
Authority: EP
Inventors: Helmut Konopa; Wolfgang Nuiding
Original assignee: BSH Bosch und Siemens Hausgeraete GmbH
Current assignee: BSH Hausgeraete GmbH
Priority date: 2004-03-15
Filing date: 2005-03-14
Publication date: 2006-12-06
Also published as: US20110232309A1; CN1930428B; RU2374573C2; CN1930428A; US20080250799A1; DE102004012498A1; RU2006130847A; WO2005090878A1; DE202005021918U1; US8020392B2

Abstract

A refrigerating appliance comprises a storage compartment (3), a refrigerant circuit (5, 7, 8), which serves to cool the storage compartment (3) and contains a compressor (7), and comprises a collecting receptacle (12) for condensed water flowing out of the storage compartment (3). The collecting receptacle (12) can be heated by a heating device (17, 25) that can be independently operated by the operation of the compressor (7).

Description

200400357

Description of refrigerator

The present invention relates to a refrigerator with a collecting or evaporation container for condensation according to the preamble of claim 1. Such a refrigerator is known from DE 198 55 504 AI. This known refrigeration device has a heat-insulating housing which encloses a storage space for refrigerated goods and has a recess open to the outside in a lower corner, in which a compressor for a refrigerant circuit of the refrigeration device is accommodated. A condensate collecting container is mounted on the housing of the compressor, which condenses in the storage chamber and drains into the collecting container through an opening formed above the collecting container in the housing.

The collecting container is mounted on the housing of the compressor in order to utilize heat loss, which the compressor generates during operation, to heat the condensation in the collecting container and thus accelerate its evaporation.

Various efforts have been made in recent years to reduce the energy consumption of the refrigeration devices. The result of these efforts is that the power consumption that the compressor must have in order to effectively cool the storage chamber becomes less and less as development progresses. In modern refrigeration devices with high-quality insulation, it can happen that the waste heat from the compressor is no longer sufficient to evaporate the defrost water at the rate at which it flows out of the storage chamber, so that the collection container eventually overflows. If the overflowing condensation water gets to live parts below the drip tray, this can damage the electrical system of the refrigerator. Condensation water escaping from the device can also lead to damage elsewhere, especially in built-in devices that are intended for installation in furniture. Problems of this kind can occur, in particular, with self-defrosting devices in which the defrost water accumulates in batches in large quantities.

The object of the present invention is to provide a refrigeration device in which an overflow of the collecting tray can be reliably avoided, even if the waste heat given off by the compressor to the collecting tray is low.

The object is achieved by a refrigerator with the features of claim 1. With the help of the independent heating device, the heating power supplied to the collecting tray can be supplemented to the extent necessary to prevent overflow.

[006] The heating device is preferably essentially formed by an ohmic resistor.

The Heinzeinrichtung can be easily on a wall of the collecting container 200400357

be arranged; In order to introduce the heat energy it releases into the condensation water contained in the collecting container with as little loss as possible, the heating device is preferably arranged to be immersed in the collecting container.

A control circuit can be provided to operate the heater periodically. If the ratio of the operating time of the heating device to the total operating time of the refrigeration device can be set on the control circuit, the average heating output can be limited to the minimum required to prevent overflow, depending on the climatic conditions under which the refrigeration device is used.

According to a preferred embodiment, a door opening sensor is provided on a door of the refrigerator, and a control circuit coupled to the door opening sensor controls the average power of the heating device according to the frequency of the detected door openings. This design is based on the consideration that each time the door is opened due to the air exchange between the storage chamber of the refrigerator and its surroundings, a certain amount of moisture is introduced into the refrigerator, and that this moisture ultimately reaches the collecting container as condensation and is evaporated from it must, so that the heating energy required for this must be provided.

According to a particularly economical embodiment, a water level sensor is arranged on the collecting container, and a control circuit coupled to the water level sensor operates the heating device when the water level detected by the water level sensor exceeds a limit value. In this embodiment, heating energy is actually only used when this is necessary to prevent overflow; Safety margins, which are required in the case of a purely time-controlled operation of the heating device, or operation based on the frequency of the door openings, in order to take account of fluctuations in the climatic conditions or the release of moisture by refrigerated goods stored in the refrigerator, do not apply here.

[011] The water level sensor is preferably formed by a float switch.

Further features and advantages of the invention will become apparent from the following description of exemplary embodiments with reference to the accompanying figures. Show it:

[013] FIG. 1 shows a schematic section through a refrigeration device according to the invention;

[014] FIG. 2 shows a compressor with a collecting container mounted therein according to a first embodiment of the invention;

3 shows a compressor with a collecting container according to a second embodiment of the invention; and

4 shows a schematic section through a collecting container with 200400357

Float switch.

The refrigeration device shown schematically in section in FIG. 1 comprises a heat-insulating housing with a body 1 and a door 2 articulated thereon, which enclose a storage chamber 3. An evaporator 5 is arranged on the rear side of the storage chamber 3, which is divided into compartments by a plurality of shelves 4. The evaporator 5 is shown here as a plate-shaped body which is inserted between a wall of the insulating container of the body 1 delimiting the interior space 3 and an insulating foam filling 6. A refrigerant circuit extends from a high-pressure outlet of a compressor 7 via a condenser 8 attached to the outside of the rear of the body 1 and the evaporator 5 to a suction connection of the compressor 7. The compressor 7 is in a recess 9 near the floor on the rear of the body 1 housed below the evaporator 5.

Humidity from the interior 3, which condenses on the wall cooled by the evaporator 5, collects at the lower edge of this wall in a drainage channel 10 and from there reaches a bowl-shaped collecting container 12 via a drain pipe 11 guided through the foam filling 6 , which is mounted on the compressor 7 to be heated by its waste heat.

The air humidity generated by evaporation from the collecting container 12 in the niche 9 is washed away by an air flow which, driven by the condenser 8 in a chimney between the rear wall of the body 1 and a... Opposite, not shown Heat or furniture wall emitted heat, initially through an intake duct 15 guided along the underside of the body 1, then through the recess 9 and finally through the chimney into the open.

Fig. 2 shows a perspective view of a special embodiment of the upper part of the compressor 7 and the collecting container 12 mounted thereon. The collecting container 12 has here in its bottom 13 an opening into which an upper section of the housing of the compressor 7 is inserted in a sealed manner , The water in the collecting container 12 therefore comes into direct contact with the housing of the compressor 7, so that the waste heat given by the compressor 7 during operation is absorbed by the condensation water with high efficiency.

By inserting the upper housing part 14 directly into the base 13, it is possible, as shown in FIG. 2 in deviation from the schematic representation of FIG. 1, a pressure connection 15 and suction connection 16 of the compressor 7 through the collecting container 12 and therein to conduct condensed water contained. The suction port 16, which is flowed through by the evaporator 5, relaxed and cold refrigerant is provided with an insulating jacket; the pressure connection 15 through which compressed, warm refrigerant flows to the condenser 8, 200400357

is not insulated, so that heat can also be released from the refrigerant to the defrost water. In order to intensify this effect, a pipe section (not shown in the figure) can be provided between the pressure connection 15 and the condenser 8, which runs through the condensation water in a loop or meandering manner.

[023] An electrically operated heating rod 17 dips into the collecting container 12 from above and extends in the form of a loop. It is supplied with energy by a control circuit 18 (see FIG. 1).

[024] According to a simple embodiment, the control circuit 18 comprises a timer which switches the heating element 17 on and off with a fixed period. The proportion of the switch-on period in each period can also be fixed in the simplest case, since in a refrigerator used in a warm environment, the amount of liquid that is entered into the storage chamber 3 each time the door is opened and ultimately evaporated in the collecting container 12 is larger than in a cold environment used refrigerator, but at the same time the proportion of the compressor runtime in the total operating time of the refrigerator is higher in a warm environment than in a cold one, so that more waste heat from the compressor 7 is also available for evaporation. The duration of the operating phases 17 can, however, also be adjustable on the control circuit 18 in order to take into account the influence of the ambient climate or of other environmental factors which vary from device to device on the amount of condensation water.

According to a second further development, a door opening sensor 19 is connected to the control circuit 18, which is e.g. can be a magnetic field sensor exposed to the magnetic field of a magnetic seal of the door 2 or simply a switch, which is usually provided on every refrigerator for switching the interior lighting of the storage chamber 3 on and off depending on the open state of the door 2. The control circuit 18 counts the door opening processes reported by this door opening sensor 19 and, after a predetermined number of detected door openings, sets the heating element 17 in motion for a predetermined period of time, which is predetermined by the manufacturer in such a way that the waste heat of the compressor 7 together with that of the Heating rod 17 would have to be sufficient to evaporate an estimated amount of moisture entered through the door openings.

[026] In a third further developed embodiment, the control circuit 18 is connected to a water level sensor 20 attached to the collecting container 12 instead of to a door opening sensor. 4 shows a schematic section of the collecting container 12 provided with such a water level sensor 20. The water level sensor 20 is designed here as a float switch, with an electrical switch 22 that can be actuated via an elongated arm 21 and one at the free end of the arm 21 200400357

attached floating body immersed in the condensation water of the collecting container 12. When the water level in the collecting container 12 exceeds a critical value, the switch 22 closes and the heating element 17 is supplied with electrical energy until the water level 24 has dropped below the critical value again ,

Fig. 3 shows a further embodiment of the collecting container 12 mounted on the upper part 14 of the housing of the compressor 7. While the upper part 14 of the housing is shown in perspective, the collecting container 12 is shown cut open in half in order to show a heating wire 25 which is in several Windings is attached to the inner surface of the collecting container 12. Since the heating wire 25 is supported by the collecting container 12, it does not need to be stiff like the heating rod 17. The collecting container 12 can be provided on its outside with an insulation layer (not shown) in order to ensure that heat given off by the heating wire 25 is completely absorbed by the condensation in the collecting container 12 and is not lost to the environment via the outer surfaces of the collecting container 12.

A temperature sensor 26 attached to the inside of the collecting container 12 near the heating wire 25 serves here as a sensor for the water level in the collecting container 12. When the heating wire is in operation, the temperature detected by the temperature sensor 26 depends on whether it and areas of the heating resistor 25 adjacent to it are below the water level or not. If the temperature detected by this sensor 26 during each operation of the heating wire 25 is above an empirically determined limit value, it can be concluded that these areas of the heating wire 25 adjacent to the temperature sensor 26 do not immerse in the condensation water and that it is consequently not necessary Operate heating wire 25. That With this configuration, a control circuit 18 connected to the temperature sensor 26 can occasionally start up the heating wire 25 in order to judge the water level in the collecting container 12 based on the heating of the temperature sensor 26, and if the assessment shows that the water level is not critical is, the operation of the heating wire 25 is immediately stopped again, otherwise it is continued - possibly with an increased performance compared to the previous test phase - until the water level has dropped below a critical level and this results in an increase in the temperature detected by the sensor 26 reflects.

Such a temperature sensor 26 could also be attached directly to the heating element 17 in the embodiment of FIGS. 2 and 4. It is also conceivable to use the heating wire 25 or heating rod 17 itself as a temperature sensor if its heating resistor has a temperature-dependent resistance value, the measurement of which by the control circuit 18 provides information as to whether the heating wire 25 or the heating rod 17 7

is cooled by condensed water or not.

Claims

200400357

Expectations

Refrigeration device with a storage chamber (3), a refrigerant circuit (5, 7, 8) for cooling the storage chamber (3), which contains a compressor (7), and a collecting container (12) for collecting the from the storage chamber (3 ) emerging condensation, characterized in that the collecting container (12) can be heated by a heating device (17, 25) which can be operated independently of the operation of the compressor (7).

Refrigerating appliance according to claim 1, characterized in that the heating device (17, 25) comprises an ohmic resistor.

Refrigeration device according to claim 1 or 2, characterized in that the heating device (25) is arranged on a wall of the collecting container.

Refrigeration device according to claim 1 or 2, characterized in that the heating device (17) is arranged immersed in the collecting container.

Refrigerating appliance according to one of the preceding claims, characterized by a control circuit (18) for periodically operating the heating device.

Refrigerating appliance according to one of claims 1 to 4, characterized by a door opening sensor (19) arranged on a door (2) of the refrigerating appliance and a control circuit (18) coupled to the door opening sensor (19) for controlling the average power of the heating device (17 ) according to the frequency of the recorded door openings.

Refrigerating appliance according to one of claims 1 to 4, characterized by a on the collecting container (12) arranged water level sensor (20) and a to the water level sensor (20) coupled control circuit (18) for operating the heating device (17) when the the water level sensor (20) detected water level exceeds a limit.

[008] Refrigeration device according to claim 7, characterized in that the water level sensor (20) is a float switch.

Refrigerating appliance according to one of claims 1 to 4, characterized in that a time measuring device and a control circuit (18) coupled thereto for operating the heating device (17) is provided when a predetermined time period has been reached.

Refrigerating appliance according to one of claims 1 to 9, characterized in that the collecting container is arranged such that it is acted upon by the waste heat of the compressor (7).