DE9404036U1 - Fridge with fan ventilation and improved indoor ventilation - Google Patents

Description

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Refrigerator with fan ventilation and improved internal ventilation

The invention relates to a refrigerator with fan ventilation, such as a free-standing refrigerator or the like, in which at least one refrigerator compartment and one freezer compartment in a cupboard compartment are separated by a partition wall and in which air ducts in the cupboard compartment enable the circulation of cooling air between said compartments.

In known refrigerators, said compartments are provided with a single opening for the admission of air into the compartment, said opening leading to said air ducts and generally being arranged in the upper part of the compartment into which it opens. An opening for the return flow (to the ducts or to the other compartment) is generally arranged in the lower part of the compartment.

In these conventional designs, air circulation is not optimal at every point because it is hindered by the food that is in the usual refrigerator compartments. In particular, the food on the bottom and bottom of the compartment is not sufficiently cooled by air, so that it can become covered with ice, which is an unmistakable disadvantage.

Furthermore, insufficient air circulation can lead to the food not being properly preserved in the refrigerator, so there is a risk of spoilage.

The object of the invention is to create a refrigerator with at least one compartment in which the cooling air circulation is optimal.

A further task is to specify a refrigerator of the type mentioned which operates reliably and economically, which has compartments which are easy to clean and which

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has completely comparable production costs with the well-known, fan-ventilated refrigerators.

These and other objects, which will be clear to the person skilled in the art, are achieved with a refrigerator as defined in the characterizing part of claim 1.

The present invention will become clearer from the accompanying drawings, which are given as non-limiting examples only. In them:

Fig. 1 is a schematic cross-section through a free-standing refrigerator of the invention along the line 1-1 in Fig. 2,

Fig. 2 is a cross-section along the line 2-2 in Fig. 1,
Fig. 3 is a cross-section along the line 3-3 in Fig. 2,

Fig. 4 is an enlarged cross-section similar to that in Fig. 1 through part of a modified version of the refrigerator according to Fig. 1,

Fig. 5 is a perspective view of a part of the refrigerator part according to Fig. 4,

Fig. 6 is a view similar to Fig. 2 of a further embodiment of the invention and

Fig. 7 is a cross-section taken along line 7-7 in Fig. 6.

In the figures, a free-standing refrigerator or household refrigerator 1 has a cupboard compartment 2 containing a cooling compartment 3 and a freezing compartment 4, both of which are provided with their own locking doors, not shown.

The refrigerator 1 has fan ventilation (forced ventilation

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type) and has in the cupboard compartment 2 a channel 6 on the rear wall 7 of the refrigerator compartment 3, a channel 8 in the partition wall 10 separating the compartments 3 and 4 and a channel 11 which connects the compartment 3 to a gap 12 provided on the back of the rear wall 13 of the compartment 4. The gap 12 contains a conventional evaporator 15 for the refrigerator 1 and a conventional fan 16 for conveying cold air from the gap 12 to the channels 6 and 8 and to the compartment 4.

The channel 6 opens into the compartment 3 via a plurality of openings 20. These openings 20 (feed openings) enable a uniform supply of cooling air to the compartment 3, so that the cooling air can flow around the food (not shown) stored on each of the usual shelves (also not shown) in the compartment 3. In order to optimize the air circulation in the compartment 3, the feed openings are arranged in superimposed, parallel planes (indicated by lines F, G...M in Fig. 2), the distances between which become increasingly smaller from the partition wall 10 to the upper wall of the compartment 3. Alternatively or in addition to this feature of the planes F...M, the feed openings 20 can have a cross-section that decreases in the direction from the openings in plane F to the openings in plane M.

As shown in Figures 2 and 3, two (vertical) columns with openings 20 are provided in the compartment 3. These openings are formed in a protruding part 28 located on the wall 7 of the compartment 3 and open into channels 29 and 30 which are arranged laterally from the channel 6 and are connected to it.

Freezer compartment 4 also benefits from better distributed air circulation through this compartment.

This is achieved by providing the wall 13 of the compartment 4 with a plurality of openings 19 which are directed onto the

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Fan 16 is aligned and arranged radially in a projecting part 31 of the wall 13 so that the forced cooling air is directed evenly to every point of the compartment 4 (as indicated by the arrows K in Figures 1 and 2).

Near its lower end, the wall 13 also has a return flow opening 32 opening into the intermediate space 12, so that the cooling air supplied to the compartment 4 (as indicated by the arrow D in Fig. 1) can flow back to the fan (after flowing around the evaporator 15 and thus the air has been cooled).

The channel 11, which is connected to the compartment 4 via an opening 33, opens into the intermediate space 12, as already mentioned. This channel opens into the compartment 3 near the wall 10 via a passage 34 provided in the compartment wall 7.

During operation of the refrigerator 1, the cooling air is driven by the fan 16 into the duct 6 and then through the openings 20 into the compartment 3. The cooling air goes from the duct 6 through the above-mentioned supply openings into the compartment 3 with a different flow, which depends on the position (planes F...M) of the openings and on the opening cross-section. More precisely, the flow through the openings 20 in the plane F is the greatest, while that through the openings 20 in the plane M is the smallest.

The cooling air then flows from compartment 3 via the passage 34 and the channel 11 into the intermediate space 12, which the cooling air also reaches from compartment 4 via the opening 32. From the intermediate space 12, the cooling air repeats the described circulation under the effect of the fan.

In the manner described, the cooling air can reach each point of the compartment 3 or 4 in a substantially uniform manner

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so that refrigerator performance and food preservation are improved.

Figures 4 and 5 show modifications of the invention. In these figures, parts designated by the same reference numerals correspond to those already described. As can be seen from these figures, the rear wall 13 of the compartment 4 is formed by pressing, this rear wall comprising the projecting part 31 from which a projecting channel 38 provided with slots 40 extends. The slots 40 (with different cross-sections depending on the distance of the slots from the partition 10) and the openings 19 direct the cooling air onto the usual shelves 50 in the compartment 4. This cooling air flows back to the intermediate space 12 via the opening 32, above which a grid 33 is preferably arranged.

Figures 6 and 7 show a further embodiment according to the invention. In these figures, parts provided with the same reference numerals correspond to those already described.

In these figures, the duct 6 is provided in a corner part 60 of the compartment 3. The openings 20 supplying the cooling air to the compartment 3 are provided in this corner part and are in communication with the duct 6. A similar corner part 61 is also provided on the rear wall 7 of the compartment 3, which receives the duct 11; it has the passage 34 for receiving the cooling air from the compartment 3, which is arranged near the upper compartment wall 22. The usual light 62 for the compartment 3 is arranged near this passage.

In this embodiment, the evaporator 15 consists of two separate parts 15A, 15B, which are arranged in associated chambers 12A, 12B of the intermediate space 12 and are separated by a wall 12C. The first part 15A does not have the usual cooling fins, but only the usual cooling gas circulation pipes, while the second part 15B is provided with heat-conducting

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the cooling fins.

The cooling air flowing from compartment 3 through channel 11 leaves opening 33 in chamber 12A of space 12 and deposits most of its moisture on the tubes of evaporator section 15A, thereby avoiding the formation of ice on second evaporator section 15B (which would be an obvious disadvantage). The cooling air then flows into chamber 12B, is directed to second evaporator section 15B and is then driven by fan 16 into compartment 4. This circulation increases the efficiency of heat exchanger 15 in that most of the ice is formed on first heat exchanger section 15A contained in chamber 12A, where, however, the probability of clogging is less due to the shape of section 15A.

This results in improved and more effective heat transfer between the finned part 15B and the cooling air. This increases the time between the defrosting phases and reduces energy consumption.

The cooling air supplied by the fan to compartment 4 normally returns through opening 32. However, when compartment 4 requires a larger volume of cooling air to reduce the compartment temperature (this requirement is detected by a sensor), the cooling air is supplied to compartment 3 by a fan 65 which is arranged below the gap 12 and which forces the cooling air from compartment 4 into compartment 3 via duct 6 and opening 20. In this way, fan 65 takes advantage of the cooling air from compartment 4 which has already cooled this compartment to a low temperature and which can therefore be used to cool compartment 3 to a temperature above 0 ⁰ C.

The fan 65 replaces the normal flap valves for regulating the temperature in compartment 3, so that the usual pressure drop when supplying the cooling air to compartment 3

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is avoided. Compartment 3 does not require a box to house the usual temperature control elements; therefore, any wasted space in compartment 3 is avoided.

Accordingly, in the embodiment according to Figures 6 and 7, the fan 16 ventilates the compartment 4, while the fan 65 ventilates the compartment 3 by conveying at least a portion of the cooling air of the compartment 3 (a portion is used by the fan 16) and at least a portion of the cooling air supplied by the fan 16.

It should be noted that in all embodiments the channels 6, 11 and 8 are formed by blow molding the usual housing defining the structure of the cabinet compartment 2.

Some embodiments of the invention have been described. However, other embodiments are possible (for example, an embodiment in which the channel 6 is divided into two parts which open into opposite sides of the cooling compartment via supply openings) which fall within the scope of the invention.

Claims (10)

93 A 000576 m ^. — ft — isprüche 1. A refrigerator with fan ventilation and improved internal ventilation, such as a freestanding refrigerator or the like, in which at least one refrigerator compartment and one freezer compartment in a cupboard compartment are separated by a partition wall and in which air ducts in the cupboard compartment enable cooling air to circulate between said compartments, characterized in that at least one of the compartments (3, 4) is provided with a plurality of openings (19, 20, 40) through which the forced cooling air flows into the compartment after passing through at least one of the air ducts, and that these openings (19, 20, 40) are arranged in different regions of the compartment (3, 4) such that the forced cooling air can reach different regions of the compartment (3, 4). 2. Refrigerator according to claim 1, characterized in that the openings (20, 40) in the compartment (3, 4) are provided in at least one compartment wall and are arranged in superimposed, parallel planes (F, G, H, I, L, M). 3. Refrigerator according to claim 2, characterized in that the openings (20, 40) for the forced cooling air supplied to the cabinet compartment have different cross-sections, which depend on their distance from the partition wall (10) between the compartments (3, 4). 4. Refrigerator according to claim 2, characterized in that the distance between the openings (20, 40) for the forced cooling air supplied to the compartment (3, 4) increases in the direction of the partition wall (10) arranged between the compartments (3, 4). 5. Refrigerator according to claim 1, characterized in that the openings (19) for the forced cooling air supplied to the compartment (4) are arranged radially in a compartment wall (13) 93 A000576 on which a fan (16) is provided for generating the forced cooling air circulation in this compartment. 6. Refrigerator according to claim 1, characterized in that in the ventilated compartment (3, 4) a conventional opening (32, 34) is provided for the return flow of the forced cooling air to the conventional evaporator (15). 7. Refrigerator according to claim 1, characterized in that the openings (20) for the forced cooling air supplied to the compartment (3) are provided in a corner part (60) of the compartment, while in another corner part (61) at least one passage (34) for the return flow of the forced cooling air to the evaporator (15) is arranged, the air circulation channels (6, 11) being located in these corner parts (60, 61). 8. Refrigerator according to claim 6, characterized in that the passage (34) for the return flow of the forced cooling air is arranged near the roof (22) of the ventilated compartment. 9. Refrigerator according to claim 1, characterized in that the fan (16) drives the air into only one (4) of the two compartments (3, 4) and that a further fan drives forced cooling air into the other compartment (3), the further fan being connected to one of the channels (6, 8, 11) which open into the latter compartment via the cooling air openings (20). 10. Refrigerator according to claim 1, characterized in that the channels (6, 8, 11) in the housing forming the cabinet compartment (2) are produced by blow molding.