EP1284399A2 - Refrigerating apparatus - Google Patents

Abstract

A region of the wall (16) is left free of the evaporator (15). This region occupies more than one quarter of the extent of the wall.

Description

The present invention relates to a cooling device, in particular a household refrigerator.

In conventional cooling devices of this type, there is an evaporator on the rear wall of the interior attached, which extends from the upper end of the rear wall over a covers the largest possible proportion of their area. A large expansion of the evaporator is desirable to be able to cool the interior with high performance. The evaporator traditionally has to reach the top of the wall because of it cooled air of the interior flows down. This leads to temperature stratification in the interior with the warmest area on top. If the vaporizer would not extend to the top of the wall would be effective It is not possible to cool such an upper area.

One consequence of this design principle is that especially when the evaporator is standing the inner wall to which it is attached becomes damp over a large area and accordingly releases a lot of moisture into the interior. This moisture can lead to dew formation lead in the interior and on refrigerated goods stored therein, which spoils early of the refrigerated goods promotes.

The release of moisture from the cooled rear wall to the interior could indeed can be reduced by making the area of the evaporator smaller, this however, leads to the problem that the effectiveness of cooling in the lower range of the Interior suffers, especially if this lower area is separated by a compartment, in particular a vegetable compartment is taken into which a cooled on the evaporator, falling airflow cannot easily penetrate.

A cooling device according to the preamble of claim 1 is known from DE 41 31 211 C1.

The air circulation device of this cooling device sucks the air from the interior and lets it through a by extending along the rear wall of the refrigerator Flow inside through a partition separated channel, on the outside of it Wall of the evaporator is arranged. With such a cooling device is indeed suitable Design of the channels an even temperature distribution in the interior achievable, but this is at the expense of the useful volume of the interior, since the Flow channels must be separated from this. In addition, the intense Airflow helps keep moisture condensed on the evaporator Phases of the evaporator is distributed again in the interior and so the dew formation promotes refrigerated goods stored in the interior.

The object of the present invention is to provide a cooling device with a simple structure, in which the amount of water evaporable from the cooled inner wall and so that the humidity in the interior can be kept low.

The object is achieved in that the area of the inner wall occupied by the evaporator compared to conventional refrigeration devices, so that at least a quarter or even half of the area of the wall remains free from the evaporator, and that the free area forms an upper area of the wall. In this way the Effectiveness of cooling in the lower area, in particular in the area of a vegetable compartment, not reduced, and effective cooling in the upper area, in which the Evaporator does not extend is forced by one using the air circulation device Air exchange causes.

In the cooling device according to the invention, it is not necessary that the air circulation device circulated air flow directly over the entire surface of the evaporator to be led; a partition that has a flow channel on the entire surface of the evaporator separating from the interior, as described in DE 41 31 211 C1, is therefore not mandatory. Because no voluminous flow channel is separated from the interior good space utilization is achieved.

The evaporator of the cooling device according to the invention is preferably a cold wall evaporator trained, i.e. it is between the wall of the interior and one behind it embedded thermal insulation layer.

The air circulation device is preferably arranged and constructed so that one of their flow distribution generated in the interior is a zone of maximum flow velocity at a distance from the wall equipped with the evaporator. That on the wall of the evaporator it can be relatively "windless", so on it Thaw the deposited moisture as far as possible when the evaporator is at a standstill, drain and can be removed from the interior of the refrigerator, instead of again to evaporate in this.

This type of flow distribution does not exclude the cooling device according to the invention for effective air circulation with flow channels separated from the interior is equipped in which also higher flow speeds than in the interior may occur.

Preferably, the interior of the refrigerator is in an upper area and one of at least one box-like container occupied lower compartment, and the evaporator extends into the area of the compartment to include the contents of the container effective cooling. To an uneven distribution of temperature in the lower To avoid the area, the outer sides of the container are preferably at least on part of its area from an air flow caused by the air circulating device lapped.

Fig. 1

zeigt in einem schematischen Schnitt ein erfindungsgemäßes Kühlgerät.

Figs. 2 und 3

zeigen jeweils schematisch einen Blick in den Innenraum eines Kühlgeräts gemäß einer zweiten bzw. dritten Ausgestaltung der Erfindung.

Fig. 4

zeigt einen horizontalen Schnitt durch die Rückwand des Kühlgeräts aus Fig. 3.

Further features and advantages of the present invention result from the following description of an exemplary embodiment with reference to the attached figures.

Fig. 1

shows in a schematic section an inventive cooling device.

Figs. 2 and 3

each schematically show a view into the interior of a cooling device according to a second or third embodiment of the invention.

Fig. 4

shows a horizontal section through the rear wall of the cooling device from FIG. 3.

A cooling device 10 designed as a multi-temperature refrigerator has in the middle Section of its heat-insulated housing 11 has a door 12 on its front side closable interior 13. The one struck on the side of the door opening on the housing 11 Door 12 is on its inside with projecting, one above the other Provide storage compartments 14 which serve to hold small-sized items to be refrigerated. in the Inside the cooling compartment 13 is located on the rear wall 16 of the thermally insulated housing 11 a planar evaporator 15 in the form of a so-called cold wall evaporator, which extends in the horizontal direction over the full width of the rear wall 16 extends. An upper region 17 of the rear wall, which is about at least a quarter, better one third and in the example shown here about half the height of the interior remains free from the evaporator 15; the evaporator 15 extends down to under a partition plate 18 which divides the interior 13 into an upper region 19 and a lower one Compartment 20 divided. The lower compartment 20 is arranged by one or two side by side Pull-out boxes 21 filled for vegetables or the like. The Partition plate 18 is a closed plate, e.g. made of glass that has a horizontal passage 27 limited along the top of the box 21. A second passage 28 runs between the front of the box 21 and the door 12, below the box bottom and between the back of the box 21 and the back wall 16.

An air circulation device 22 in the form of a fan is under the ceiling of the interior 13, in this embodiment in the vicinity of the door 12, arranged and generated a downward airflow 24.

The downward directed air flow 24 generated by the fan 22 becomes on shelves 23 of the interior, which is preferably designed as a grid because of the good flowability and, if necessary, on (not shown) on the shelves 23 Refrigerated goods are scattered, so that a widely distributed, diffuse air flow separates the partition plate 18 reached, flows in part through the passages 27 and 28 and along the rear wall 16 slowly flows up again. Since the shelves 23 do not block the air flow, they can extend directly to the rear wall 16.

Of course, the shelves 23 can also be closed, e.g. in the form of Glass plates. In this case there are gaps 25 between the rear edges of the shelves 23 and the rear wall 16 are provided so that the upward air flow along the Rear wall 16 can run through the column 25.

In both cases, this upward flow cools the interior 13 also reached above the evaporator 15. Because the evaporator 15 or more precisely said the area of the rear wall 16, behind which it is arranged, not directly from Air flow 24 of the fan 22 is flowed, the flow does not cause any significant Increasing the evaporation of condensed water on the evaporator 15.

Due to the relatively small area of the Evaporator 15 collects in its operating phases per unit area of the evaporator and time unit a relatively large amount of condensate on this. The time that passes until droplets are formed that are large and heavy enough to form from the condensate to flow downward on the rear wall 16 and via one formed at the lower end thereof Discharge channel 26 to be led outside is therefore comparatively short. The Amount of condensed water which is present on the evaporator 15 during a stationary phase remains and can evaporate again into the interior 13 is for this reason relatively small, so that a low humidity in the interior 13 can be maintained can.

Of course, the fan 22 can do so at various other locations on the refrigerator be arranged so that it generates the required circulation flow inside it. For example, be placed on the rear wall 16 above the evaporator 15. Conceivable is also to drive the circulating flow in the opposite direction so that this flows downward on the evaporator 15 and first on the partition plate 18 to the lower compartment 20 hits before it rises again along the door 12. With this direction of circulation is not exclude that partial areas of the evaporator by a direct or little Scattered air flow can be taken by the fan 22, so that in these areas condensed moisture can evaporate back into the interior 13. However, this can be accepted in moderation, since, as described above, already through the Reduction of the evaporator area a more efficient drainage of condensate the interior 13 results.

2 shows a schematic front view of a cooling device according to a second embodiment the invention elements of this refrigerator, which are also in the refrigerator of Fig.1 occur are provided with the same reference numerals as there and are not described in detail again. For the sake of clarity, the door and Pull-out boxes in the lower compartment 20 omitted. The evaporator 15 does not extend over the entire width of the rear wall 16, instead an edge region of the rear wall remains 16 free from the evaporator, and extends in this edge area behind the rear wall 16 in this embodiment, a flow channel 29 extends over the entire Height of the interior 13. It is at its upper and lower ends and in Height of the passage 27 between the plate 18 and the pull-out box (not shown) provided with air inlet and outlet slots 30, 31. A fan (not shown) is in the flow channel 29 between the level of the plate 18 and its upper Arranged at the end.

The fan generates an upward air flow in the flow channel 29, see above that air is drawn out through the lower slots 30 and through the upper slots 31 again is expelled. In this way, the flow around the pull-out box is also off the upper region 19 of the interior is supplied with moderately cold air, while freshly cooled air sucked off at the evaporator 15 and at the upper end of the flow channel 29 is expelled again. This is an effective cooling of the entire upper area 19 is guaranteed and at the same time the content of the pull-out box protected from hypothermia by the closely adjacent evaporator 15.

FIG. 3 shows a modification of the illustration in FIG. 2, in which the flow channel 29 extends centrally over the rear wall 16. As the horizontal section of FIG. 4 shows the rear wall 16 bulges into the interior 13 in the region of the flow channel 29, and the air flow in the flow channel 29 runs directly along the surface of the evaporator 15. The effect in this embodiment is essentially that same as that of Fig. 2; the only difference is that the air passes undergoes additional cooling through the flow channel 29. You can in the flow channel 29 quite higher flow speeds than in the interior 13 occur; however, this is not critical to the desired drying effect. The only decisive factor here is that the lateral sections 32 of the evaporator 15 on both sides of the flow channel 29, each only through the material of the rear wall 16 are separately in direct thermal contact with the interior 13 and the form a predominant part of the surface of the evaporator by means of a suitable flow distribution in the interior are protected from the flow, so that there is condensate can collect and flow undisturbed at these sections 32.

Claims (6)

Cooling device (10) with an interior (13), an evaporator (15) arranged on a wall (16) of the interior (13) and an air circulation device (22) effective in the interior (13), characterized in that one of the evaporators ( 15) free area (17) of the wall (16) extends at least over an upper quarter of this. Cooling device according to claim 1, characterized in that the evaporator (15) is provided in the lower half of the wall (16). Cooling device according to claim 1 or 2, characterized in that the evaporator (15) is designed as a cold-wall evaporator. Cooling device according to one of the preceding claims, characterized in that a flow distribution generated by the air circulation device (22) in the interior has a zone (24) of maximum flow velocity at a distance from the wall (16) equipped with the evaporator (15). Cooling device according to one of the preceding claims, characterized in that the interior (13) is divided into a lower compartment (20) occupied by at least one box-like container (2), the evaporator (15) extending into the compartment (20) , Cooling device according to claim 5, characterized in that the outside of the container (21) is washed at least on part of its surface by an air flow caused by the air circulation device (22).

Images