DE102022207353A1 - Refrigeration device - Google Patents

Abstract

A refrigeration device comprises a storage compartment for holding refrigerated goods, a machine room that is separate from the storage compartment, a fan arranged in the machine room and which is designed to promote an air flow through the machine room, a first condensate container for receiving condensation that occurs in the storage compartment, which a bottom and a peripheral wall protruding from the bottom, and a second condensate container for receiving condensate water accumulating in the storage compartment, which has a bottom and a peripheral wall protruding from the bottom. The first condensate container has a first depth defined by its peripheral wall. The second condensate container has a second depth defined by its peripheral wall. Furthermore, the second condensate tank is arranged adjacent to the first condensate tank with respect to a vertical direction that extends transversely to the bottom of the first condensate tank and to the bottom of the second condensate tank. The peripheral wall of the second condensate container projects in relation to the vertical direction over an end of the peripheral wall of the first condensate container located away from the floor, so that it protrudes into an area of the machine room through which the air flow conveyed by the fan flows, and that the second depth of the second condensate container is smaller than the first depth of the first condensate container.

Description

TECHNICAL FIELD

The present invention relates to a refrigeration appliance, in particular a household refrigeration appliance such as a refrigerator, a freezer or a chest freezer or a fridge-freezer combination.

STATE OF THE ART

In refrigeration appliances, in particular in household refrigeration appliances, condensate that accumulates in a refrigeration compartment is typically directed into a condensate container arranged outside the refrigeration compartment in a machine room. The condensate container is usually thermally coupled to a refrigerant compressor of the refrigeration device, so that its waste heat is used to evaporate the condensate water located in the condensate container.

As the efficiency of the refrigerant compressors increases, the waste heat available to evaporate the condensation water decreases. In order to still achieve sufficient evaporation performance, one approach is to provide several evaporation trays in the machine room. However, this conflicts with the fact that there is only limited space available in the engine room.

In the DE 10 2019 200 631 A1 A refrigeration device is described in which, in order to increase the evaporation capacity within an evaporation tray, a further tray is arranged on a pipe section through which refrigerant compressed by the compressor flows.

The CN 110906636 A discloses a refrigeration device in which a heat exchanger assembly with a compact condenser and a fan is provided in the machine room. The compact condenser is drum-shaped with a central opening in which an additional condensate container is arranged.

SUMMARY OF THE INVENTION

It is one of the objects of the present invention to provide improved solutions for the absorption and evaporation of condensation in a refrigeration appliance, in particular solutions that have a space-saving structure and yet allow sufficient evaporation of condensation.

This object is achieved according to the invention by a refrigeration device with the features of claim 1.

According to the present invention, a refrigeration device, in particular a household refrigeration device such as a refrigerator, a freezer or a chest freezer or a refrigerator-freezer combination, comprises a storage compartment for holding refrigerated goods, a machine room separate from the storage compartment, a fan arranged in the machine room, which for this purpose is designed to promote an air flow through the machine room, a first condensate container for receiving condensate water accumulating in the storage compartment, which has a floor and a peripheral wall protruding from the floor, and a second condensate container for receiving condensate water accumulating in the storage compartment, which has a Bottom and a peripheral wall protruding from the bottom. The first condensate container has a first depth defined by its peripheral wall. The second condensate container has a second depth defined by its peripheral wall. Furthermore, the second condensate tank is arranged adjacent to the first condensate tank with respect to a vertical direction that extends transversely to the bottom of the first condensate tank and to the bottom of the second condensate tank.

Accordingly, according to the invention, a first condensate container or a first evaporation tray and a second condensate container or second evaporation tray arranged in relation to a vertical direction above the first condensate container are provided in the machine room. The bottom of the second condensate container is thus arranged at a distance in the vertical direction from the bottom of the first condensate container. The circumferential walls of the first and second condensate containers each extend along the vertical direction and define, with respect to the vertical direction, a depth of the respective condensate container. The depth of the respective condensate container can be defined in particular by a distance, measured in the vertical direction, from an end of the circumferential wall located away from the floor to a point on an inner surface of the floor facing the end of the circumferential wall.

According to the invention it is further provided that the circumferential wall of the second condensate container protrudes in relation to the vertical direction over an end of the circumferential wall of the first condensate container which is located away from the floor, so that it protrudes into an area of the machine room through which the air flow conveyed by the fan flows, and that the second depth of the second condensate container is smaller than the first depth of the first condensate container.

According to the invention, a large or deep first condensate container and a flat or less deep second condensate container arranged above the first condensate container. On the one hand, this includes an arrangement in which the bottom of the second condensate container is located above the end of the peripheral wall of the first condensate container with respect to the vertical direction. That is, the end of the peripheral wall of the first condensate tank is disposed in the vertical direction between the bottoms of the first and second condensate tanks. On the other hand, it can also be provided that the bottom of the second condensate container is located in the vertical direction between the bottom and the end of the peripheral wall of the first condensate container, so that the peripheral walls of the first and second condensate containers overlap in the vertical direction.

Because the circumferential wall of the second condensate container protrudes in relation to the vertical direction over an end of the circumferential wall of the first condensate container located away from the floor, the second, flat condensate container protrudes into the air flow that is conveyed by the fan. The air thus passes over the surface of the condensate in the second condensate container, which promotes the evaporation of the condensate. Since the second condensate container is designed with a shallow depth compared to the first condensate container, the condensate that collects in it can evaporate very quickly. In addition, the second condensate tank is flat. On the one hand, this creates a space-saving structure. On the other hand, the second condensate container advantageously represents only a small flow resistance for the air flow generated by the fan. The second condensate container advantageously increases the surface area of the collected condensate water.

Advantageous refinements and further developments result from the subclaims referring back to the independent claims in conjunction with the description.

According to some embodiments, it can be provided that the bottom of the second condensate container is designed as a flat or essentially flat plate. By designing it as a plate-shaped, flat floor, the overall height of the second condensate container can advantageously be further reduced.

According to some embodiments, it can be provided that the bottom of the second condensate container has an inner surface oriented away from the first condensate container, from which the peripheral wall protrudes and from which a plurality of ribs protrude, the ribs together delimiting a plurality of fields for collecting condensate. The ribs can in particular have a smaller height in relation to the vertical direction than the peripheral wall of the second condensate container. For example, the ribs can extend transversely, for example orthogonally, to one another and cross each other. As a result, several ribs together delimit a field in which condensation can collect. In this way, an uneven distribution of the condensate over the inner surface of the bottom of the second condensate container can be prevented, for example if it is arranged at an angle with respect to the direction of gravity.

According to some embodiments, it can be provided that the second depth of the second condensate container is in a range between 5 percent and 45 percent of the first depth of the first condensate container. In particular, it can be provided that the second depth of the second condensate container is in a range between 5 percent and 30 percent of the first depth of the first condensate container or between 10 percent and 30 percent of the first depth of the first condensate container. The second depth of the second condensate container is therefore significantly smaller than the first depth of the first condensate container.

According to some embodiments, it can be provided that the second depth of the second condensate container is in a range between 0.5 cm and 2 cm.

According to some embodiments, it can be provided that the second condensate container is positioned relative to the first condensate container in such a way that the bottom of the second condensate container is located completely within the peripheral wall of the first condensate container with respect to a horizontal direction extending transversely to the vertical direction. The second condensate container can therefore be smaller in terms of its circumference than the first condensate container. That is, the bottoms of the first and second condensate tanks can be arranged to completely overlap with respect to the horizontal direction.

According to some embodiments, it can be provided that the second condensate container has an overflow, which is designed such that it allows condensate water to overflow from the second condensate container into the first condensate container. For example, it can be provided that the second condensate container is dimensioned and positioned relative to the first condensate container in such a way that the second condensate container is positioned in relation to a horizontal direction extending transversely to the vertical direction is located completely within the peripheral wall of the first condensate container, and that the overflow is formed by an end of the peripheral wall of the second condensate container located away from the floor. This means that a recess or something similar does not necessarily have to be provided in the peripheral wall of the second condensate container, but rather water flows directly over the edge of the peripheral wall of the second condensate container from the second condensate container into the first condensate container. The structural design of the second condensate container is thus further simplified.

According to some embodiments, it can be provided that a condensate line extends between the storage compartment and the machine room in order to drain condensate from the storage compartment, and wherein the second condensate container is positioned relative to the condensate line in such a way that it opens into the second condensate container. One end of the condensate water line can thus be arranged above the second condensate container or above the bottom of the second condensate container with respect to the vertical direction. In this way it is achieved that condensate is always absorbed first in the second condensate container. Only when this is full does the condensate overflow into the first condensate container. Due to the shallow depth of the second condensate container, a large amount of condensate can be efficiently evaporated before it is full.

According to some embodiments, it can be provided that an inner surface of the bottom of the second condensate container facing the condensation water line forms a depression in the area of the condensation water line. This is particularly advantageous when there is a small distance between the bottom of the second condensate container and the end of the condensate water line, for example to prevent the condensate water line from hitting the bottom of the second condensate container, for example during transport.

According to some embodiments, it can be provided that the machine room has a suction opening and a discharge opening, the fan being arranged such that it sucks air into the machine room through the suction opening and ejects it through the discharge opening, and wherein the first and second condensate containers are between the Suction opening and the discharge opening are arranged. The suction opening and the discharge opening can be formed, for example, on opposite side walls of the machine room. The condensate containers are generally arranged to extend into a straight connecting corridor connecting the suction and discharge ports.

According to some embodiments, it can be provided that the refrigeration device has a refrigerant circuit that is thermally coupled to the storage compartment and is designed to extract heat from the storage compartment and release it to the environment, the refrigerant circuit comprising a heat exchanger assembly arranged in the machine room, which includes the fan and a Condenser for condensing the refrigerant, and wherein the fan is arranged and designed to direct the air flow over the condenser. The condenser can be implemented, for example, as a compact condenser, in particular as an MCHE condenser, where “MCHE” is an abbreviation for the English expression “Multi Channel Heat Exchanger”. An advantage of these embodiments is that the heat exchanger assembly has a space-saving structure. Another advantage is that the air flow is used both to evaporate the condensation and to remove heat from the condenser, which further improves the energy efficiency of the refrigeration device.

According to some embodiments, it can be provided that the first and second condensate containers are arranged downstream of the condenser in the air flow conveyed by the fan. That is, the first and second condensate tanks are arranged relative to the heat exchanger assembly such that the fan directs air first over the condenser and then to the condensate tanks. The air conveyed by the fan heats up at the condenser. Since the condensate containers are located downstream of the heat exchanger assembly with respect to the flow direction of the air flow promoted by the fan, the heated air further increases the evaporation performance.

According to some embodiments, it can be provided that the refrigerant circuit has a compressor for circulating the refrigerant in the refrigerant circuit, the compressor being connected to the condenser by a pressure line, and the pressure line extending partially within the first condensate container and/or the first condensate container is arranged in thermally conductive contact with the compressor. In this way, the evaporation of condensate from the first condensate container can be further increased.

According to some embodiments, it can be provided that the refrigeration device has a further condensate container which has a base and a peripheral wall protruding from the base, the further condensate container having a third depth defined by its peripheral wall, which is smaller than the first depth of the first condensate container , with the further condensate container in relation to the vertical direction, is arranged adjacent to the second condensate container, and wherein the peripheral wall of the further condensate container protrudes in relation to the vertical direction over an end of the peripheral wall of the second condensate container located away from the floor and thereby protrudes into an area of the machine room through which the air flow conveyed by the fan flows . Accordingly, several flat condensate containers can be provided one above the other in the manner described above. The further condensate container or containers can be constructed in the same way as the second condensate container described above. By providing additional flat condensate containers that protrude into the air flow of the fan, the evaporation performance can advantageously be further increased.

According to some embodiments, it can be provided that the third depth of the further condensate container is equal to the second depth of the second condensate container.

BRIEF DESCRIPTION OF THE DRAWINGS

• 1 eine vereinfachte, schematische Schnittansicht eines Kältegeräts gemäß einem Ausführungsbeispiel der Erfindung;
• 2 eine perspektivische Teilansicht der Anordnung eines ersten und eines zweiten Kondensatbehälters im Maschinenraum eines Kältegeräts gemäß einem Ausführungsbeispiel der Erfindung; und
• 3 eine vereinfachte, schematische Schnittansicht der Anordnung eines ersten und eines zweiten Kondensatbehälters im Maschinenraum eines Kältegeräts gemäß einem weiteren Ausführungsbeispiel der Erfindung.

The invention is explained below with reference to the figures in the drawings. Of the figures show:

• 1 a simplified, schematic sectional view of a refrigeration device according to an embodiment of the invention;
• 2 a partial perspective view of the arrangement of a first and a second condensate container in the machine room of a refrigeration appliance according to an exemplary embodiment of the invention; and
• 3 a simplified, schematic sectional view of the arrangement of a first and a second condensate container in the engine room of a refrigeration appliance according to a further exemplary embodiment of the invention.

In the figures, the same reference numbers designate the same or functionally identical components, unless otherwise stated.

DETAILED DESCRIPTION OF EMBODIMENTS

1 shows, by way of example and purely schematically, refrigeration device 100 in the form of a refrigerator. In general, the refrigeration device 100 can be a household refrigeration device, such as a refrigerator, a freezer or a freezer or a refrigerator-freezer combination.

As in 1 Shown schematically, the refrigeration device 100 has a storage compartment 1 for holding refrigerated goods, a machine room 2 separate from the storage compartment 1, a refrigerant circuit 3, a first condensate container 4 and a second condensate container 5.

The machine room 2 can be separated from the storage compartment 1 by a partition 12, for example. The partition 12 can, as in 1 shown purely as an example, on the one hand form a floor of the storage compartment 1 and on the other hand a ceiling wall of the machine room 2. The machine room 2 is limited by the ceiling wall with respect to a vertical direction X3. Furthermore, the machine room can be delimited, for example, by opposing side walls 21, 22 with respect to a horizontal direction X1 extending transversely to the vertical direction X3.

As in 1 is also shown, a condensation water line 6 can be provided, which is intended to drain condensation water from the storage compartment 1, for example into the machine room 2. As in 2 shown schematically, the condensation water line 6 can extend, for example, through the partition 12 into the machine room 2. In general, the condensation water pipe 6 ends in the engine room 2.

The refrigerant circuit 3 is thermally coupled to the storage compartment 1 and is designed to extract heat from the storage compartment 1 and to release the heat to the environment. As in 1 shown schematically, the refrigerant circuit 3 can have, for example, a compressor 31, an evaporator 32, a heat exchanger assembly 33 with a condenser 34 and a fan 35 and a throttle (not shown). The compressor 31 is connected to the evaporator 32 with a suction inlet and to the condenser 34 with a pressure outlet, for example via a pressure line 31A, as in 1 shown schematically. The throttle is arranged between the condenser 34 and the evaporator 32. The compressor 31 circulates a refrigerant in the refrigerant circuit 3, the evaporator 32 absorbing heat from the storage compartment 1 by evaporating refrigerant, and the condenser 34 releasing heat to the environment by condensing the refrigerant.

As in 1 shown schematically, the compressor 31 and the heat exchanger assembly 33 can be accommodated in the engine room 2. The fan 35 is arranged relative to the condenser 34 and is designed to direct an air flow over the condenser 34. In this case, the condenser 34 is preferably designed as a compact condenser. In principle, it is also conceivable that a condenser of the refrigerant circuit 3 is arranged outside the engine room 2, for example a passive condenser, and Only one fan 35 is provided in the engine room 2. The fan 35 is generally designed to promote an air flow LS through the engine room 2. As in 1 shown by way of example, the engine room 2 can have a suction opening 25, which can be formed, for example, in the side wall 21, and an exhaust opening 26, which is as shown in 1 shown can be formed, for example, in the side wall 22. In this case, the fan 35 can be arranged in such a way that it sucks air into the engine room 2 through the suction opening 25 and expels it through the discharge opening 26. That is, a suction side of the fan 35 faces the suction port 25, and a pressure side of the fan 35 faces the discharge port.

The first and second condensate containers 4, 5 are as in 1 shown schematically, arranged in the machine room 2 in order to absorb the condensation drained from the storage compartment 1 via the condensation water pipe 6. 1 shows a purely schematic representation of the condensate containers 4, 5. In 2 the condensate containers 4, 5 are shown as examples with more details.

In general, the first condensate container 4 has a bottom 40 and a peripheral wall 41 which extends transversely to the bottom 40 or protrudes from the bottom 40. The bottom 40 extends flat, for example as a flat plate as in 1 shown schematically. Alternatively, the bottom 40 of the first condensate container 4 can also have a curved, for example dome-shaped, shape, as shown in 2 is shown as an example. A peripheral shape of the bottom 40 is not limited to a specific shape. For example, the bottom can have a substantially rectangular circumference, as in 2 presented purely as an example. The peripheral wall 41 extends transversely to the floor 40, in particular from an inner surface 40a of the floor 40 to an end 41B located away from the floor 40, and forms a closed circumference. The peripheral wall 41 and the bottom 40 thus delimit a receiving volume that is open on one side for receiving condensation. The peripheral wall 41 defines a first depth t4 of the first condensate container 4. As in 1 shown schematically, the depth t4 can be measured in particular from the bottom 40 or the inner surface 40a to the end 41B of the peripheral wall.

As in 1 shown schematically, the first condensate container 4 can be placed on the compressor 31, for example. In particular, an outer surface of the bottom 40 of the first condensate container 4, which is oriented opposite to the inner surface 40a, can have a shape that is designed to correspond to an outer contour of the compressor. In general, it can be provided that the first condensate container 4 is arranged in thermally conductive contact with the compressor 31. Alternatively or additionally, it can be provided that the pressure line 31A, which connects the compressor 31 to the condenser 34, extends partially within the first condensate container 4, as shown in FIG 2 is shown as an example. As in 1 Shown schematically, the first condensate container 4 is arranged in the machine room 2 in such a way that the vertical direction X3 extends transversely to the floor 40. The peripheral wall 41 thus extends essentially along the vertical direction X3. The inner surface 40a of the floor 40 is oriented facing the partition 12 or the ceiling of the machine room 2.

The second condensate container 5 has a bottom 50 and a circumferential wall 51 which extends transversely to the bottom 50 or protrudes from the bottom 50. The bottom 50 extends flat, for example as a flat or essentially flat plate, as shown in FIGS 1 and 2 is shown schematically. A peripheral shape of the bottom 50 is not limited to a specific shape. For example, the bottom can have a substantially rectangular circumference, as in 2 presented purely as an example. The peripheral wall 51 extends transversely to the base 50, in particular from an inner surface 50a of the base 50 to an end 51B located away from the base 50, and forms a closed circumference. The peripheral wall 51 and the bottom 50 thus delimit a receiving volume that is open on one side for receiving condensation. The peripheral wall 51 defines a second depth t5 of the second condensate container 5. As in 1 shown schematically, the depth t5 can be measured in particular from the bottom 50 or the inner surface 50a to the end 51B of the peripheral wall. Like in the 1 and 2 each shown schematically, the second depth t5 of the second condensate container 5 is significantly smaller than the first depth t4 of the first condensate container 4. The second depth t5 of the second condensate container 5 can, for example, be in a range between 5 percent and 45 percent of the first depth t4 of the first Condensate container 4 lies. For example, it can be provided that the second depth t5 of the second condensate container 5 is in a range between 0.5 cm and 2 cm.

As in 2 Also shown as an example, it can be provided that the bottom 50 is formed with a plurality of ribs 52 on the inner surface 50a of the second condensate container 5. The ribs 52 protrude from the inner surface 50a. The ribs 52 can, for example, each extend between two spaced points of the peripheral wall 51, for example linearly or straight, as in 2 shown as an example. Furthermore, each rib 52 intersects at least one further rib 52. For example the ribs 52 can run orthogonally to one another, as in 2 shown purely as an example. In general, the ribs 52 together delimit a plurality of fields 54 on the inner surface 50a of the bottom 50 of the second condensate container 5. These fields 54 each serve to hold condensate and counteract an uneven distribution of the condensate water within the second condensate container 5, for example when this is in relation to the direction of gravity is oriented obliquely. As in 2 shown, the ribs 52 can in particular have a smaller height than the peripheral wall 50 of the second condensate container 5.

As in 1 Shown schematically, the second condensate container 5 is arranged adjacent to the first condensate container 4 in relation to the vertical direction X3 in the machine room 2, in particular directly adjacent to the first condensate container 4. In other words, the second condensate container 5 is located between the first condensate container 4 and the partition 12 or the ceiling of the machine room 2. The second condensate container 5 is positioned or aligned in such a way that the vertical direction X3 is transverse to the bottom 50 of the second condensate container 5 extends. The peripheral wall 51 of the second condensate container 5 thus extends essentially in the vertical direction X3.

Like in particular 1 can be seen, the second condensate container 5 can be located, for example, completely above the end 41B of the peripheral wall 41 of the first condensate container 4 with respect to the vertical direction X3. However, the invention is not limited to this. Alternatively, it is also conceivable that although the end 51B of the peripheral wall 51 of the second condensate container 5 is located above the end 41B of the peripheral wall 41 of the first condensate container 4 with respect to the vertical direction X3, the bottom 50 of the second condensate container 5 is located between the end 41 B the peripheral wall 41 of the first condensate container 4 and the bottom 40 of the first condensate container 4 is located. In general, it is provided that the peripheral wall 51 of the second condensate container 5 protrudes the end 41 B of the peripheral wall 41 of the first condensate container 4 with respect to the vertical direction X3. As a result, the peripheral wall 51 of the second condensate container 5 protrudes into an area of the machine room 2 through which the air flow LS conveyed by the fan 35 flows. Like in particular 2 can be seen, the volume of the second condensate container 5 is very small compared to that of the first condensate container, since the depth t5 of the second condensate container 5 is significantly smaller than the depth t4 of the first condensate container 4. Due to this flat design of the second condensate container 5 and its arrangement in the air flow LS, a high evaporation rate can be achieved. As in 1 Shown schematically and purely as an example, the first and second condensate containers 4, 5 can be arranged downstream of the condenser 34 in the air flow LS conveyed by the fan 35, for example on the pressure side of the fan 35, with the condenser 35 on the suction side, as in 1 shown as an example, or can be arranged on the pressure side of the fan 35. Heating the air at the condenser 34 helps to further increase the evaporation performance. In general, the first and second condensate containers 4, 5 can be arranged between the suction opening 25 and the discharge opening 26 and thereby in the air flow LS.

The second condensate container 5 can generally be attached to the first condensate container 4. For example, it is conceivable that the bottom 50 of the second condensate container 5 rests on the end 41B of the peripheral wall 41 of the first condensate container 4. Alternatively, it is conceivable that the second condensate container 5 is fixed to a base 44 projecting from the bottom 40 or the inner surface 40a of the first condensate container 4, as shown in FIG 2 shown purely as an example. Other options for fixing the condensate containers 4, 5 to one another are also conceivable.

Like in the 1 and 2 shown as an example, the second condensate container 5 can be dimensioned and positioned relative to the first condensate container 4 in such a way that the bottom 50 of the second condensate container 5, in particular with respect to the horizontal direction X1, is located completely within the peripheral wall 41 of the first condensate container 4. Alternatively, the second condensate container 5 can also protrude laterally or in relation to the horizontal direction X1 beyond the peripheral wall 41 of the first condensate container 4.

As in 1 shown, it can advantageously be provided that the second condensate container 5 is arranged below the condensation water line 6. This means that the second condensate container 5 is positioned relative to the condensate water line 6 so that it opens into the second condensate container 5. The condensate water line 6 therefore ends in relation to the horizontal direction of the second condensate container 5 is achieved. For example, the second condensate container 5 can have an overflow 58, which is designed such that it allows condensate water to overflow from the second condensate container 5 into the first condensate container 4 light. For example, the peripheral wall 51 of the second condensate container 5 can be provided with a recess at a point located within the peripheral wall 41 of the first condensate container 4 with respect to the horizontal direction X1. Alternatively, in the case that the second condensate container 5 is dimensioned and positioned relative to the first condensate container 4 such that the second condensate container 5 is located completely within the peripheral wall 41 of the first condensate container 4 with respect to the horizontal direction End 51A of the peripheral wall 52 of the second condensate container 5 may be formed itself. As in 2 Shown schematically by the dashed line, the inner surface 50a of the bottom 50 of the second condensate container 5 can have a recess 56 in an area which is opposite the end of the condensation water line 6 in order to prevent the condensation water line 6 from hitting the bottom 50.

Based on 1 and 2 A refrigerator 100 was described in which a first and a second condensate container 4, 5 are arranged one above the other. However, the invention is not limited to two condensate containers 4, 5. In particular, additional condensate containers can be arranged above the second condensate container 5. 3 shows, purely by way of example, an arrangement with a further condensate container 7. The further condensate container 7 can be constructed essentially in the same way as the second condensate container 5. In general, the further condensate container 7 has a bottom 70 and a peripheral wall 7 protruding from the bottom 70, which a depth t7 of the further condensate container 7 is defined. The depth t7 of the further condensate container 7 is smaller than the first depth t4 of the first condensate container 4 and can, for example, be equal to the second depth t5 of the second condensate container 5. The bottom 70 of the further condensate container can, for example, have a rectangular circumference, but is not limited to this.

As in 4 Shown schematically, the further condensate container 7 is arranged adjacent to the second condensate container 5 with respect to the vertical direction X3. This means that the second condensate container 5 is arranged between the first and the further condensate container 4, 7 with respect to the vertical direction X3. As described above for the second and the first condensate container 5, 4, the peripheral wall 71 of the further condensate container 7 projects beyond the end 51 B of the peripheral wall 51 of the second condensate container 5 with respect to the vertical direction X3 and thereby protrudes into an area of the machine room 2 protrudes through which the air flow LS conveyed by the fan 35 flows.

As in 3 Also shown as an example, it can be provided that the further condensate container 7 is dimensioned and positioned relative to the second condensate container 5 in such a way that the further condensate container 7 is located completely within the peripheral wall 51 of the first condensate container 5 with respect to the horizontal direction X1. The condensate water line 6 preferably opens into the further or generally the uppermost of the further condensate containers 7.

Although the present invention has been explained above using exemplary embodiments, it is not limited to this but can be modified in a variety of ways. In particular, combinations of the above exemplary embodiments are also conceivable.

REFERENCE MARKS

1

Storage compartment

2

Engine room

3

Refrigerant circulation

4

first condensate tank

5

second condensate container

6

condensation water pipe

7

another condensate container

12

partition wall

21

Side wall

22

Side wall

25

Intake opening

26

Ejection port

31

compressor

31A

pressure line

32

Evaporator

33

Heat exchanger assembly

34

liquefier

35

Fan

40

Bottom of the first condensate container

40a

Inner surface of the bottom of the first condensate tank

41

Circumferential wall of the first condensate container

41B

End of the peripheral wall of the first condensate container

44

base

50

Bottom of the second condensate container

50a

Inner surface of the bottom of the second condensate tank

51

Circumferential wall of the second condensate container

51B

End of the peripheral wall of the second condensate container

52

Ribs

54

fields

56

deepening

58

overflow

70

Bottom of the additional condensate container

71

Circumferential wall of the additional condensate container

100

Refrigeration device

L.S

Airflow

X1

Horizontal direction

X3

Vertical direction

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was 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

• DE 102019200631 A1 [0004]
• CN 110906636 [0005]

Claims (15)

Refrigeration appliance (100), in particular household refrigeration appliance, comprising: a storage compartment (1) for holding refrigerated goods; a machine room (2) separate from the storage compartment (1); a fan (35) arranged in the engine room (2), which is designed to promote an air flow (LS) through the engine room (2); a first condensate container (4) for receiving condensate water accumulating in the storage compartment (1), which has a base (40) and a peripheral wall (41) projecting from the base (40), the first condensate container (4) having a through its peripheral wall ( 41) has a defined first depth (t4); and a second condensate container (5) for receiving condensate water accumulating in the storage compartment (1), which has a base (50) and a peripheral wall (51) projecting from the base (50), the second condensate container (5) having a through its peripheral wall (51) has a defined second depth (t5), and wherein the second condensate container (5) with respect to a vertical direction (X3) which is transverse to the bottom (40) of the first condensate container (4) and to the bottom (50) of the second Condensate container (5) extends, is arranged adjacent to the first condensate container (4); characterized in that the peripheral wall (51) of the second condensate container (5) projects in relation to the vertical direction (X3) over an end (41B) of the peripheral wall (41) of the first condensate container (4) located away from the bottom (40), so that it projects into an area of the machine room (2) through which the air flow conveyed by the fan (35) flows, and the second depth (t5) of the second condensate container (5) is smaller than the first depth (t4) of the first condensate container (4 ) is. Refrigeration device (100). Claim 1 , wherein the bottom (50) of the second condensate container (5) is designed as a flat or essentially flat plate. Refrigeration device (100). Claim 1 or 2 , wherein the bottom (50) of the second condensate container (5) has an inner surface (50a) oriented away from the first condensate container (4), from which the peripheral wall (50) protrudes and from which a plurality of ribs (52) protrude, the Ribs (52) together delimit several fields (54) for collecting condensation. Refrigeration appliance (100) according to one of the preceding claims, wherein the second depth (t5) of the second condensate container (5) is in a range between 5 percent and 45 percent of the first depth (t4) of the first condensate container (4). Refrigeration appliance (100) according to one of the preceding claims, wherein the second depth (t5) of the second condensate container (5) is in a range between 0.5 cm and 2 cm. Refrigeration appliance (100) according to one of the preceding claims, wherein the second condensate container (5) is dimensioned and positioned relative to the first condensate container (4) in such a way that the second condensate container (5) extends transversely to the vertical direction (X3). Horizontal direction (X1) is located completely within the peripheral wall (41) of the first condensate container (4). Refrigeration appliance (100) according to one of the preceding claims, wherein the second condensate container (5) has an overflow (58) which is designed such that it allows condensate water to overflow from the second condensate container (5) into the first condensate container (4). . Refrigeration device (100). Claim 7 with reference to Claim 8 , wherein the overflow (52) is formed by an end (51A) of the peripheral wall (52) of the second condensate container (5) located away from the bottom (50). Refrigeration appliance (100) according to one of the preceding claims, wherein a condensate water line (6) extends between the storage compartment (1) and the machine room (2) in order to drain condensate from the storage compartment (1), and wherein the second condensate container (5) is such is positioned relative to the condensation water line (6) so that it opens into the second condensate container (5). Refrigeration device (100). Claim 9 , wherein an inner surface (50a) of the bottom (50) of the second condensate container (5) facing the condensation water line (6) forms a depression (56) in the area of the condensation water line (6). Refrigeration appliance (100) according to one of the preceding claims, wherein the machine room (2) has a suction opening (25) and a discharge opening (26), the fan (35) being arranged such that it draws air through the suction opening (25) into the Machine room (2) sucks in and ejects through the discharge opening (26), and wherein the first and second condensate containers (4, 5) are arranged between the suction opening (25) and the discharge opening (26). Refrigeration device (100) according to one of the preceding claims, additionally comprising: a refrigerant circuit (3) thermally coupled to the storage compartment (1), which is designed to remove heat from the storage compartment (1) and release it to the environment, and one in the machine room (2) arranged heat exchanger assembly (33) comprising the fan (35) and a condenser (34) for condensing the refrigerant; wherein the fan (35) is arranged and designed to direct the air flow over the condenser (34). Refrigeration device (100). Claim 12 , wherein the refrigerant circuit (3) has a compressor (31) for circulating the refrigerant in the refrigerant circuit (3), wherein the compressor (31) is connected to the condenser (34) by a pressure line (31A), and wherein the pressure line ( 31A) extends partially within the first condensate container (4) and/or the first condensate container (4) is arranged in thermally conductive contact with the compressor (31). Refrigeration device (100). Claim 12 or 13 , wherein the first and second condensate containers (4, 5) are arranged downstream of the condenser (34) in the air flow conveyed by the fan (35). Refrigeration device (100) according to one of the preceding claims, additionally comprising: a further condensate container (7), which has a base (70) and a peripheral wall (71) projecting from the base (70); wherein the further condensate container (7) has a third depth (t7) defined by its peripheral wall (71), which is smaller than the first depth (t4) of the first condensate container (4), wherein the further condensate container (7) with respect to the vertical direction (X3), is arranged adjacent to the second condensate container (5), and wherein the peripheral wall (71) of the further condensate container (7) protrudes in relation to the vertical direction (X3) over an end (51 B) of the peripheral wall (51) of the second condensate container (5) located away from the base (50) and thereby into one Area of the machine room (2) protrudes through which the air flow (LS) conveyed by the fan (35) flows.

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